Solid-state image pickup device, signal processing method for the same, and image pickup apparatus using the same

ABSTRACT

A solid-state image pickup device includes: comparators; counters; and a control portion for carrying out control in such a way that in a phase of an addition mode, the two comparators and the two counters corresponding to the two pixel columns, respectively, are set as a unit, 1 is added to a second digit of one counter of the two counters when both the comparison results from the two comparators has a first logic, 1 is added to a first digit of the one counter when one of the comparison results from the two comparators has the first logic, and 1 is added to none of the first digit and the second digit of the one counter when both the comparison results from the two comparators has a second logic.

CROSS REFERENCES TO RELATED APPLICATIONS

The present Application is a Continuation Application of U.S. patentapplication Ser. No. 15/880,066, filed Jan. 25, 2018, which is aContinuation Application of U.S. patent application Ser. No. 14/685,074,filed Apr. 13, 2015, which issued as U.S. Pat. No. 9,912,895, which is aContinuation application of U.S. application Ser. No. 12/476,963, filedJun. 2, 2009, which issued as U.S. Pat. No. 9,036,062 May 19, 2015,which claims priority to Japanese Patent Application JP 2008-161415filed in the Japanese Patent Office on Jun. 20, 2008, and to JapanesePatent Application JP 2008-260302 filed in the Japanese Patent Office onOct. 7, 2008, the entire contents of which being incorporated herein byreference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a solid-state image pickup device, asignal processing method for the same, and an image pickup apparatususing the same, and more particularly to a solid-state image pickupdevice utilizing a so-called Column Analog-to-Digital Conversion (ADC)system, a signal processing method for the same, and an image pickupapparatus using the same.

2. Description of the Related Art

An amplification type solid-state image pickup device as one kind of X-Yaddress type solid-state image pickup device, for example, a CMOS type(including a MOS type) solid-state image pickup device (hereinafterreferred to as “a CMOS image sensor”) is known as one system ofsolid-state image pickup devices. A technique called a column system isknown in this CMOS image sensor. In the column system, column processingportions are provided independently of one another so as to correspondto pixel columns, respectively, for a pixel array portion in whichpixels including respective photo-electric conversion elements aretwo-dimensionally disposed in a matrix. Also, signals (pixel signals)are successively read out every pixel column from the respective pixelsin the pixel array portion to be temporarily held in the correspondingone of the column processing portions. Also, the pixel signals for onecolumn are successively read out at a predetermined timing.

In addition, a column Analog-to-Digital Conversion (ADC) system withwhich a column processing portion is given an ADC function is known asone kind of column system. With this column ADC system, a comparatorcompares an analog pixel signal with a reference signal having a RAMPwaveform, thereby generating a pulse signal having a size (pulse width),in a time axis direction, corresponding to a size of the pixel signal.Also, a counter counts predetermined clock signals for a time periodcorresponding to the pulse width of the pulse signal, and the resultingcount value is set as a digital signal corresponding to the size of thepixel signal. In such a manner, the AD conversion is carried out.

In the CMOS image sensor using such a column ADC system, a so-calledthinning reading method of thinning (skipping) pixel information to readout the resulting pixel information is known as a method of increasing aframe rate. However, when the thinning reading method is used, sincealthough the electric charges are accumulated through the photoelectricconversion, there are some pixels from which the electric chargesaccumulated therein are discarded, the sensitivity is reduced. In orderto solve a problem about the reduction of the sensitivity, heretofore,analog pixel signals outputted from respective unit pixels are convertedinto digital values by utilizing a column ADC system, and the resultingdigital values corresponding to a plurality of pixels in a verticaldirection, respectively, are added to one another to be read out. Thistechnique, for example, is disclosed in Japanese Patent Laid-Open No.2005-278135 (hereinafter referred to as Patent Document 1).

SUMMARY OF THE INVENTION

With the related art disclosed in Patent Document 1, there is a limit toan increase in frame rate because both the thinning reading method andthe addition for the pixels are realized only in the vertical direction.When both the thinning reading method and the addition for the pixelscan be realized in a horizontal direction as well, the frame rate can befurther increased. Here, let us consider the case where both thethinning reading method and the addition for the pixels are realized inthe horizontal direction.

A method of carrying out the addition for the pixels in a digital signalprocessing portion after information from all the pixel columns ishorizontally outputted is expected as a method of realizing both thethinning reading method and the addition for the pixels in thehorizontal direction. With this method, however, an amount ofinformation horizontally outputted is not reduced. Therefore, the framerate can be enhanced only for an increase in frame rate through theaddition for the pixels in the vertical direction, and it may beimpossible to sufficiently enhance the frame rate.

The present invention has been made in order to solve the problemdescribed above, and it is therefore desirable to provide a solid-stateimage pickup device in which addition for pixels in a horizontaldirection is realized in column ADC, thereby making it possible toreduce an amount of information horizontally outputted, a signalprocessing method for the same, and an image pickup apparatus using thesame.

In order to attain the desire described above, according to anembodiment of the present invention, there is provided a solid-stateimage pickup device including: comparators provided so as to correspondto pixel columns, respectively, for a pixel array portion having unitpixels, including respective photo-electric conversion elements,disposed in a matrix, each of the comparators serving to compare ananalog signal outputted from corresponding one of the unit pixelsthrough corresponding one of vertical signal lines with a ramp-likereference signal, for outputting a comparison result containing timeinformation corresponding to a size of corresponding one of the analogsignals; counters each of which serves to carry out a counting operationfor adding 1 to a least significant digit with one clock period based onthe time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals; and a control portion for carrying out control in such a waythat in a phase of an addition mode, the two comparators and the twocounters corresponding to the two pixel columns, respectively, are setas a unit, 1 is added to a second digit of one counter of the twocounters when both the comparison results from the two comparators has afirst logic, 1 is added to a first digit of the one counter when one ofthe comparison results from the two comparators has the first logic, and1 is added to none of the first digit and the second digit of the onecounter when both the comparison results from the two comparators has asecond logic.

Also, the solid-state image pickup device having the configurationdescribed above is used as an image pickup element (image pickup device)in a camera system such as a digital still camera or a video camera, oran electronic apparatus having an image pickup function such as a mobilephone.

In the solid-state image pickup device having the configurationdescribed above, or an image pickup apparatus using the solid-stateimage pickup device, 1 is added to the second digit of the one counterof the two counters when both the comparison results from the twocomparators have the first logic (either an “H” level or an “L” level).That is to say, 1 is counted with one clock period synchronously with aclock signal. As a result, the addition for the two pixels in thehorizontal direction can be carried out within a column processingportion. On the other hand, 1 is added to none of the first digit andthe second digit of the one counter of the two counters when both thecomparison results from the two comparators have the second logic.

According to another embodiment of the present invention, there isprovided a solid-state image pickup device including: comparatorsprovided so as to correspond to pixel columns, respectively, for a pixelarray portion having unit pixels, including respective photo-electricconversion elements, disposed in a matrix, each of the comparatorsserving to compare an analog signal outputted from corresponding one ofthe unit pixels through corresponding one of vertical signal lines witha ramp-like reference signal, for outputting a comparison resultcontaining time information corresponding to a size of corresponding oneof the analog signals; counters each of which serves to carry out acounting operation for adding 1 to a least significant digit with oneclock period based on the time information outputted from correspondingone of the comparators, for outputting the resulting count value as adigital signal corresponding to the size of the corresponding one of theanalog signals; and a control portion for controlling whether or notwhen three or more comparators and three or more counters correspondingto three or more pixel columns, respectively, are set as a unit in aphase of an addition mode, 1 is added to each of first to third digitsof one counter of the three or more counters based on the comparisonresults from the three or more comparators, and values of the firstdigit and the second digit of the one counter of the three or morecounters.

According to still another embodiment of the present invention, there isprovided a solid-state image pickup device including: comparatorsprovided so as to correspond to pixel columns, respectively, for a pixelarray portion having unit pixels, including respective photo-electricconversion elements, disposed in a matrix, each of the comparatorsserving to compare an analog signal outputted from corresponding one ofthe unit pixels through corresponding one of vertical signal lines witha ramp-like reference signal, for outputting a comparison resultcontaining time information corresponding to a size of corresponding oneof the analog signals; counters each of which serves to carry out acounting operation for adding 1 to a least significant digit with onehalf clock period based on the time information outputted fromcorresponding one of the comparators, for outputting the resulting countvalue as a digital signal corresponding to the size of the correspondingone of the analog signals; and a control portion for carrying outcontrol in such a way that in a phase of an addition mode, the twocomparators and the two counters corresponding to the two pixel columns,respectively, are set as a unit, 1 is added to a second digit of onecounter of the two counters every one half clock period when both thecomparison results from the two comparators have a first logic, 1 isadded to a first digit of the one counter every one clock period whenone of the comparison results from the two comparators has the firstlogic, and 1 is not added to the second digit of the one counter whenboth the comparison results from the two comparators have a secondlogic.

According to yet another embodiment of the present invention, there isprovided a solid-state image pickup device including: comparatorsprovided so as to correspond to pixel columns, respectively, for a pixelarray portion having unit pixels, including respective photo-electricconversion elements, disposed in a matrix, each of the comparatorsserving to compare an analog signal outputted from corresponding one ofthe unit pixels through corresponding one of vertical signal lines witha ramp-like reference signal, for outputting a comparison resultcontaining time information corresponding to a size of corresponding oneof the analog signals; counters each of which serves to carry out acounting operation based on the time information outputted fromcorresponding one of the two comparators, for outputting the resultingcount value as a digital signal corresponding to the size of thecorresponding one of the analog signals; and a control portion forcarrying out control in such a way that in a phase of an addition mode,the two comparators and the two counters corresponding to the two pixelcolumns, respectively, are set as a unit, a count portion correspondingto a first digit of one counter of the two counters is caused to carryout counting with one half clock period when both the comparison resultsfrom the two comparators have a first logic, the count portioncorresponding to the first digit of the one counter of the two countersis caused to carry out counting with one clock period when one of thecomparison results from the two comparators has the first logic, and thecount portion corresponding to the first digit of the one counter of thetwo counters is caused to stop the counting when both the comparisonresults from the two comparators have a second logic.

According to a further embodiment of the present invention, there isprovided a signal processing method for a solid-state image pickupdevice including: comparators provided so as to correspond to pixelcolumns, respectively, for a pixel array portion having unit pixels,including respective photo-electric conversion elements, disposed in amatrix, each of the comparators serving to compare an analog signaloutputted from corresponding one of the unit pixels throughcorresponding one of vertical signal lines with a ramp-like referencesignal, for outputting a comparison result containing time informationcorresponding to a size of corresponding one of the analog signals; andcounters each of which serves to carry out a counting operation foradding 1 to a least significant digit with one clock period based on thetime information outputted from corresponding one of the comparators,for outputting the resulting count value as a digital signalcorresponding to the size of the corresponding one of the analogsignals. In the signal processing method, in a phase of an additionmode, the two comparators and the two counters corresponding to the twopixel columns, respectively, are set as a unit, 1 is added to a seconddigit of one counter of the two counters when both the comparisonresults from the two comparators has a first logic, 1 is added to afirst digit of the count value of the one counter when one of thecomparison results from the two comparators has the first logic, and 1is added to none of the first digit and the second digit of the countvalue of the one counter when both the comparison results from the twocomparators has a second logic.

When both the comparison results from the two comparators have the firstlogic (either an “H” level or an “L” level), 1 is added to the seconddigit of the one counter of the two counters. That is to say, 1 iscounted with one clock period synchronously with a clock signal. As aresult, the addition for the two pixels in the horizontal direction canbe carried out within a column processing portion. On the other hand,when both the comparison results from the two comparators have thesecond logic, 1 is added to none of the first digit and the second digitof the one counter of the two counters.

According to an even further embodiment of the present invention, thereis provided a signal processing method for a solid-state image pickupdevice including: comparators provided so as to correspond to pixelcolumns, respectively, for a pixel array portion having unit pixels,including respective photo-electric conversion elements, disposed in amatrix, each of the comparators serving to compare an analog signaloutputted from corresponding one of the unit pixels throughcorresponding one of vertical signal lines with a ramp-like referencesignal, for outputting a comparison result containing time informationcorresponding to a size of corresponding one of the analog signals; andcounters each of which serves to carry out a counting operation foradding 1 to a least significant digit with one clock period based on thetime information outputted from corresponding one of the comparators,for outputting the resulting count value as a digital signalcorresponding to the size of the corresponding one of the analogsignals. In the signal processing method, it is controlled whether ornot when in a phase of an addition mode, the three or more comparatorsand the three or more counters corresponding to three or more pixelcolumns, respectively, are set as a unit, 1 is added to each of first tothird digits of one counter of the three or more counters based on thecomparison results from the three or more comparators, and values of thefirst digit and the second digit of the one counter of the three or morecounters.

According to a still further embodiment of the present invention, thereis provided a signal processing method for a solid-state image pickupdevice including comparators provided so as to correspond to pixelcolumns, respectively, for a pixel array portion having unit pixels,including respective photo-electric conversion elements, disposed in amatrix, each of the comparators serving to compare an analog signaloutputted from corresponding one of the unit pixels throughcorresponding one of vertical signal lines with a ramp-like referencesignal, for outputting a comparison result containing time informationcorresponding to a size of corresponding one of the analog signals; andcounters each of which serves to carry out a counting operation foradding 1 to a least significant digit with one half clock period basedon the time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals. In the signal processing method, in a phase of an additionmode, the two comparators and the two counters corresponding to the twopixel columns, respectively, are set as a unit, 1 is added to a seconddigit of one counter of the two counters every one half clock periodwhen both the comparison results from the two comparators have a firstlogic, 1 is added to a first digit of the one counter of the twocounters every one clock period when one of the comparison results fromthe two comparators has the first logic, and 1 is not added to a seconddigit of the one counter when both the comparison results from the twocomparators have a second logic.

According to a yet further embodiment of the present invention, there isprovided a signal processing method for a solid-state image pickupdevice including: comparators provided so as to correspond to pixelcolumns, respectively, for a pixel array portion having unit pixels,including respective photo-electric conversion elements, disposed in amatrix, each of the comparators serving to compare an analog signaloutputted from corresponding one of the unit pixels throughcorresponding one of vertical signal lines with a ramp-like referencesignal, for outputting a comparison result containing time informationcorresponding to a size of corresponding one of the analog signals; andcounters each of which serves to carry out a counting operation foradding 1 to a least significant digit with one half clock period basedon the time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals. In the signal processing method, in a phase of an additionmode, the two comparators and the two counters corresponding to the twopixel columns, respectively, are set as a unit, a count portioncorresponding to a first digit of one counter of the two counters iscaused to carry out counting with one half clock period when both thecomparison results from the two comparators have a first logic, thecount portion corresponding to the first digit of the one counter of thetwo counters is caused to carry out counting with one clock period whenone of the comparison results from the two comparators has the firstlogic, and the count portion corresponding to the first digit of the onecounter of the two counters is caused to stop the counting when both thecomparison results from the two comparators have a second logic.

According to another embodiment of the present invention, there isprovided an image pickup apparatus including: a solid-state image pickupdevice; and an optical system for imaging an incident light on animaging area of the solid-state image pickup device. The solid-stateimage pickup device includes: comparators provided so as to correspondto pixel columns, respectively, for a pixel array portion having unitpixels, including respective photo-electric conversion elements,disposed in a matrix, each of the comparators serving to compare ananalog signal outputted from corresponding one of the unit pixelsthrough corresponding one of vertical signal lines with a ramp-likereference signal, for outputting a comparison result containing timeinformation corresponding to a size of corresponding one of the analogsignals; counters each of which serves to carry out a counting operationfor adding 1 to a least significant digit with one clock period based onthe time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals; and a control portion for carrying out control in such a waythat in a phase of an addition mode, the two comparators and the twocounters corresponding to the two pixel columns, respectively, are setas a unit, 1 is added to a second digit of one counter of the twocounters when both the comparison results from the two comparators has afirst logic, 1 is added to a first digit of the one counter when one ofthe comparison results from the two comparators has the first logic, and1 is added to none of the first digit and the second digit of the onecounter when both the comparison results from the two comparators has asecond logic.

According to still another embodiment of the present invention, there isprovided an image pickup apparatus including: a solid-state image pickupdevice; and an optical system for imaging an incident light on animaging area of the solid-state image pickup device. The solid-stateimage pickup device includes: comparators provided so as to correspondto pixel columns, respectively, for a pixel array portion having unitpixels, including respective photo-electric conversion elements,disposed in a matrix, each of the comparators serving to compare ananalog signal outputted from corresponding one of the unit pixelsthrough corresponding one of vertical signal lines with a ramp-likereference signal, for outputting a comparison result containing timeinformation corresponding to a size of corresponding one of the analogsignals; counters each of which serves to carry out a counting operationfor adding 1 to a least significant digit with one clock period based onthe time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals; and a control portion for controlling whether or not when threeor more comparators and three or more counters corresponding to three ormore pixel columns, respectively, are set as a unit in a phase of anaddition mode, 1 is added to each of first to third digits of onecounter of the three or more counters based on the comparison resultsfrom the three or more comparators, and values of the first digit andthe second digit of the one counter of the three or more counters.

According to yet another embodiment of the present invention, there isprovided an image pickup apparatus including: a solid-state image pickupdevice; and an optical system for imaging an incident light on animaging area of the solid-state image pickup device. The solid-stateimage pickup device includes: comparators provided so as to correspondto pixel columns, respectively, for a pixel array portion having unitpixels, including respective photo-electric conversion elements,disposed in a matrix, each of the comparators serving to compare ananalog signal outputted from corresponding one of the unit pixelsthrough corresponding one of vertical signal lines with a ramp-likereference signal, for outputting a comparison result containing timeinformation corresponding to a size of corresponding one of the analogsignals; counters each of which serves to carry out a counting operationfor adding 1 to a least significant digit with one half clock periodbased on the time information outputted from corresponding one of thecomparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals; and a control portion for carrying out control in such a waythat in a phase of an addition mode, the two comparators and the twocounters corresponding to the two pixel columns, respectively, are setas a unit, 1 is added to a second digit of one counter of the twocounters every one half clock period when both the comparison resultsfrom the two comparators have a first logic, 1 is added to a first digitof the one counter every one clock period when one of the comparisonresults from the two comparators has the first logic, and 1 is not addedto the second digit of the one counter when both the comparison resultsfrom the two comparators have a second logic.

According to a further embodiment of the present invention, there isprovided an image pickup apparatus including: a solid-state image pickupdevice; and an optical system for imaging an incident light on animaging area of the solid-state image pickup device. The solid-stateimage pickup device includes: comparators provided so as to correspondto pixel columns, respectively, for a pixel array portion having unitpixels, including respective photo-electric conversion elements,disposed in a matrix, each of the comparators serving to compare ananalog signal outputted from corresponding one of the unit pixelsthrough corresponding one of vertical signal lines with a ramp-likereference signal, for outputting a comparison result containing timeinformation corresponding to a size of corresponding one of the analogsignals; counters each of which serves to carry out a counting operationbased on the time information outputted from corresponding one of thetwo comparators, for outputting the resulting count value as a digitalsignal corresponding to the size of the corresponding one of the analogsignals; and a control portion for carrying out control in such a waythat in a phase of an addition mode, the two comparators and the twocounters corresponding to the two pixel columns, respectively, are setas a unit, a count portion corresponding to a first digit of one counterof the two counters is caused to carry out counting with one half clockperiod when both the comparison results from the two comparators have afirst logic, the count portion corresponding to the first digit of onecounter of the two counters is caused to carry out the counting with oneclock period when one of the comparison results from the two comparatorshas the first logic, and the count portion corresponding to the firstdigit of the one counter of the two counters is caused to stop thecounting when both the comparison results from the two comparators havea second logic.

According to the embodiments of the present invention, the addition forthe two pixels in the horizontal direction can be carried out within thecolumn processing portion, thereby making it possible to reduce theamount of information horizontally outputted to one half while thesensitivity is maintained. As a result, it is possible to realize theenhancement of the frame rate, and the reduction of the powerconsumption.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a system configuration diagram showing an outline of aconfiguration of a CMOS image sensor to which an embodiment of thepresent invention is applied;

FIG. 2 is a circuit diagram showing a circuit configuration of a unitpixel in the CMOS image sensor shown in FIG. 1;

FIG. 3 is a block diagram showing a basic configuration of a columnprocessing portion having an AD conversion function in the CMOS imagesensor shown in FIG. 1;

FIG. 4 is a conceptual diagram explaining an operation of the columnprocessing portion having a basic configuration;

FIG. 5 is a block diagram showing a configuration of a column processingportion in an image pickup device according to Embodiment 1 of thepresent invention;

FIG. 6 is a conceptual diagram explaining an operation of the columnprocessing portion in the image pickup device according to Embodiment 1of the present invention;

FIG. 7 is a diagram showing an arrangement of color filters used in anexplanation of the operation of the column processing portion in theimage pickup device according to Embodiment 1 of the present invention;

FIG. 8 is a block diagram showing a configuration of a column processingportion according to Change of Embodiment 1;

FIG. 9 is a block diagram showing a configuration of a column processingportion in an image pickup device according to Embodiment 2 of thepresent invention;

FIGS. 10A to 10C are respectively diagrams showing relationships betweencomparison results Vco(i−1), Vco(i) and Vco(i+1) from three comparators,and values R1 and R2 of count portions of first and second digits of acounter, and control for the count portions of the first to thirddigits;

FIG. 11 is a diagram showing an arrangement of color filters used in anexplanation of the operation of the column processing portion in theimage pickup device according to Embodiment 2 of the present invention;

FIG. 12 is a block diagram showing a configuration of a columnprocessing portion in an image pickup device according to Embodiment 3of the present invention;

FIG. 13 is a circuit diagram, partly in block, showing a concretecircuit configuration of an LSB count portion belonging to a pixelcolumn i (an LSB circuit belonging to an even-numbered column);

FIGS. 14A and 14B are respectively timing waveforms each showing asituation of changes in potential at a node LT, inverting control pulseaffx, and potential at a node FO;

FIG. 15 is a circuit diagram showing a circuit configuration of a countportion of a second digit belonging to a pixel column i;

FIG. 16 is a circuit diagram showing a concrete circuit configuration ofan LSB count portion belonging to a pixel column (i+1) (an LSB circuitbelonging to an odd-numbered column);

FIG. 17 is a block diagram showing a configuration of a columnprocessing portion in an image pickup device according to Embodiment 4of the present invention;

FIG. 18 is a timing chart showing a timing relationship of control inthe column processing portion in the image pickup device according toEmbodiment 4 of the present invention;

FIG. 19 is a diagram, partly in circuit, showing a relationship betweencomparators and pixels when addition for (2.times.2) pixels inhorizontal and vertical directions is carried out;

FIG. 20 is a flow chart explaining a processing procedure when additionfor pixels in both horizontal and vertical directions is carried out;and

FIG. 21 is a block diagram showing a configuration of an image pickupapparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will be described indetail hereinafter with reference to the accompanying drawings.

[System Configuration]

FIG. 1 is a system configuration diagram showing a configuration of asolid-state image pickup device, for example, a CMOS image sensor towhich an embodiment of the present invention is applied.

As shown in FIG. 1, the CMOS image sensor 10 to which an embodiment ofthe present invention is applied includes a pixel array portion 11formed on a semiconductor substrate (chip) (not shown), and peripheralcircuit portions integrated on the same semiconductor substrate as thatof the pixel array portion 11. For example, a vertical drive portion 12,a column processing portion 13, a horizontal drive portion 14, and asystem control portion 15 are provided as the peripheral circuitportions.

Unit pixels (hereinafter referred simply to as “pixels” in some cases)each including a photoelectric conversion element for photoelectricallyconverting a visible light made incident thereto into an amount ofelectric charges corresponding to a light quantity of the visible lightare two-dimensionally disposed in a matrix in the pixel array portion11. A concrete configuration of the unit pixel will be described later.

A pixel drive line 16 is formed along a horizontal direction (adisposition direction of the pixels belonging to a pixel row) of FIG. 1every row, and a vertical signal line 17 is formed in a verticaldirection (a disposition direction of the pixels belonging to a pixelcolumn) of FIG. 1 every column for matrix-like pixel disposition in thepixel array portion 11. Although one pixel drive line 16 is shown inFIG. 1 every row, the present invention is by no means limited thereto.One ends of the pixel drive lines 16 are connected to output terminalscorresponding to the rows of the vertical drive portion 12,respectively.

The vertical drive portion 12 is composed of a shift register, anaddress decoder, and the like. In this case, although a concreteconfiguration is omitted here in illustration thereof, the verticaldrive portion 12 includes a read scanning system, and a sweep scanningsystem. The read scanning system successively selects and scans the unitpixels from which pixel signals are intended to be read out,respectively, in rows.

On the other hand, the sweep scanning system carries out sweep scanningfor sweeping (resetting) unnecessary electric charges from photoelectricconversion elements of the unit pixels of a read row earlier than theread scanning by a time of a shutter speed for the read row for whichthe read scanning is carried out by the read scanning system. Aso-called electronic shutter operation is carried out by sweeping(resetting) the unnecessary electric charges by the sweep scanningsystem. Here, the electronic shutter operation means an operation fordiscarding the photoelectric charges from the photoelectric conversionelements, and newly starting exposure (starting to accumulate thephotoelectric charges).

A signal read out in the read operation by the read scanning systemcorresponds to a quantity of light which is made incident either in theimmediately preceding read operation, or in and after the electronicshutter operation. Also, a time period from either a timing at readingby the immediately preceding read operation, or a timing at sweeping bythe electronic shutter operation to a timing at reading by the presentread operation is a time period for accumulation of the photoelectriccharges in the unit pixel (a time period for exposure).

The signals which are outputted from the unit pixels belonging to thepixel row selected and scanned by the vertical drive operation 12 aresupplied to the column processing portion 13 through the respectivevertical signal lines 17. The column processing portion 13 is a signalreading circuit portion having an AD conversion function of reading outdigital signals while the analog signal outputted from the pixels 20belonging to the selected row are converted into the digital signalsevery pixel column of the pixel array portion 11. A detailed circuitconfiguration and a circuit operation of the column processing portion13 will be described later.

The horizontal drive portion 14 is composed of a shift register, anaddress decoder, and the like, and selects the column processingportions 13 in order. The pixel signals digitized in the columnprocessing portions 13 are outputted in order through the selection andscanning by the horizontal drive portion 14.

The system control portion 15 is composed of a timing generator forgenerating various kinds of timing signals, and the like. Also, thesystem control portion 15 carries out drive and control for the verticaldrive portion 12, the column processing portion 13, the horizontal driveportion 14, and the like in accordance with the various kinds of timingsignals generated in the timing generator.

(Circuit Configuration of Unit Pixel)

FIG. 2 is a circuit diagram showing a circuit configuration of the unitpixel 20. As shown in FIG. 2, the unit pixel 20 includes a photoelectricconversion element, a photodiode 21, and four transistors of, forexample, a transfer transistor 22, a reset transistor 23, anamplification transistor 24, and a selection transistor 25.

In this case, for example, N-channel MOS transistors are used as thefour transistors 22 to 25, respectively. However, a combination ofconductivity types of the transfer transistor 22, the reset transistor23, the amplification transistor 24, and the selection transistor 25exemplified here is merely an example, and thus the present invention isby no means limited thereto.

For the unit pixels 20, for example, three drive wirings of a transferline 161, a reset line 162, and a selection line 163 are provided as apixel drive line 16 commonly to the pixels belonging to the same pixelrow. One ends of the transfer line 161, the reset line 162, and theselection line 163 are connected to output terminals corresponding oneof the pixel rows of the vertical drive portion 12 in pixel rows.

An anode electrode of the photodiode 21 is connected to a negative sidepower source (for example, the ground). Also, the photodiode 21photoelectrically converts a light received thereon into photoelectriccharges (photoelectrons in this case) having a charge amountcorresponding to a light quality of the received light. On the otherhand, a cathode electrode of the photodiode 21 is electrically connectedto a gate electrode of the amplification transistor 24 through thetransfer transistor 22. A node 26 electrically connected to the gateelectrode of the amplification transistor 24 is called a FloatingDiffusion (FD) portion.

The transfer transistor 22 is connected between the cathode electrode ofthe photodiode 21, and the FD portion 26. A transfer pulse .phi.TRF inwhich a high level (for example, a Vdd level) is active (hereinafterdescribed as “high active”) is applied to the gate electrode of thetransfer transistor 22 through corresponding one of the transfer lines161. As a result, the transfer transistor 22 is turned ON, therebytransferring the photoelectric charges obtained through thephotoelectric conversion in the photodiode 21 to the FD portion 26.

A drain electrode of the reset transistor 23 is connected to the pixelpower source Vdd, and a source electrode thereof is connected to the FDportion 26. A high active reset pulse .phi.RST is applied to a gateelectrode of the reset transistor 23 through corresponding one of thereset lines 162. As a result, the reset transistor 23 is turned ON, sothat the FD portion 26 is reset by discarding the electric charges inthe FD portion 26 to the pixel power source Vdd prior to the transfer ofthe signal electric charges from the photodiode 21 to the FD portion 26.

A gate electrode of the amplification transistor 24 is connected to theFD portion 26, and a drain electrode thereof is connected to the pixelpower source Vdd. Also, the amplification transistor 24 outputs apotential at the FD portion 26 after the potential at the FD portion 26is reset by the reset transistor 23 as a reset signal (reset level)Vreset. Moreover, the amplification transistor 24 outputs a potential atthe FD portion 26 after the signal electric charges are transferred tothe FD portion 26 by the transfer transistor 22 as a photo-accumulationsignal (signal level) Vsig.

For example, a drain electrode of the selection transistor 25 isconnected to a source electrode of the amplification transistor 24, anda source electrode thereof is connected to corresponding one of thevertical signal lines 17. A high active selection pulse .phi.SEL isapplied to a gate electrode of the selection transistor 25 throughcorresponding one of the selection lines 163. As a result, the selectiontransistor 25 is turned ON, so that the unit pixel 20 is set in aselection state, and the selection transistor 25 relays the signaloutputted from the amplification transistor 24 to corresponding one ofthe vertical signal lines 17.

It should be noted that a circuit configuration in which the selectiontransistor 25 is connected between the pixel power source Vdd and thedrain electrode of the amplification transistor 24 can also be adoptedfor the selection transistor 25.

In addition, the unit pixel 20 is by no means limited to one having thepixel configuration composed of the four transistors configured asdescribed above. For example, a pixel configuration composed of threetransistors one of which is used both as the amplification transistor 24and the selection transistor 25 may also be adopted. Thus, aconfiguration of the pixel circuit is no object.

In the CMOS image sensor 10 having the configuration as described above,the features of the present invention is the circuit configuration andcircuit operation of the column processing portion 13 having the ADconversion function.

(Basic Configuration of Column Processing Portion Having AD ConversionFunction)

A basic configuration and operation of the column processing portion 13will now be described prior to giving a description with respect toconcrete embodiments of the column processing portion 13 having the ADconversion function in the CMOS image sensor of the present invention.

FIG. 3 is a block diagram, partly in circuit, showing a basicconfiguration of the column processing portion 13 having the ADconversion function. In this case, there is shown a circuitconfiguration about two pixel columns of an i-th column and an (i+1)-thcolumn. Here, since the two pixel columns i and i+1 are the pixelcolumns adjacent to each other, they can also be said as an odd-numbered(or an even-numbered) pixel column, and an even-numbered (or anodd-numbered) pixel column.

As shown in FIG. 3, the column processing portion 13 includescomparators 31 i and 31 i+1, and counters 32 i and 32 i+1 which are eachprovided so as to correspond to the two pixel columns i and i+1,respectively.

The comparators 31 i and 31 i+1 receive analog pixel signals Vsig(i) andVsig(i+1) inputted thereto through the vertical signal lines 17 i and 17i+1 at one input terminals thereof, respectively, and receive referencesignals REF each having a RAMP waveform (ramp-like waveform) at theother input terminals thereof, respectively. The reference signal REF issupplied from a reference signal generating portion (not shown). Each ofthe comparators 31 i and 31 i+1 compares both the input signals witheach other. For example, when the pixel signals Vsig(i) and Vsig(i+1)are each lower in level than the reference signal REF, the comparators31 i and 31 i+1 output comparison results Vco(i) and Vco(i+1) each at an“H” level. On the other hand, when the pixel signals Vsig(i) andVsig(i+1) are each higher in level than the reference signal REF, thecomparators 31 i and 31 i+1 output comparison results Vco(i) andVco(i+1) each at an “L” level. Here, the comparison results Vco(i) andVco(i+1) each at the “H” level are pulse signals having sizes (timeinformation/pulse width), in a time axis direction, corresponding tosizes of the pixel signals Vsig(i) and Vsig(i+1), respectively.

The counters 32 i and 32 i+1 carry out counting operations synchronouslywith a clock signal CK having a given period for a time period for whichthe comparison results Vco(i) and Vco(i+1) from the comparators 31 i and31 i+1 are each held at the “H” level. The counters 32 i and 32 i+1output count values as digital signals corresponding to the sizes of thepixel signals Vsig(i) and Vsig(i+1), respectively. As shown in FIG. 4,while the comparison results Vco(i) and Vco(i+1) are each held at the“H” level, the counter 32 i and 32 i+1 carry out the counting one by onesynchronously with the clock signal CK. On the other hand, while thecomparison results Vco(i) and Vco(i+1) are each held at the “L” level,the counter 32 i and 32 i+1 carry out no counting.

Hereinafter, column processing portions 13A to 13D in image pickupdevices according to Embodiments 1 to 4 of the present invention will bedescribed in detail on the basis of the basic configuration of thecolumn processing portion 13 having the AD conversion function describedabove.

Embodiment 1

FIG. 5 is a block diagram, partly in circuit, showing a configuration ofthe column processing portion 13A in the image pickup device ofEmbodiment 1. In the figure, the same portions as those in FIG. 3 aredesignated with the same reference numerals or symbols, respectively. Inthis case, a circuit configuration of two pixel columns of an i-thcolumn, and an (i+1)-th column is shown with two pixel columns as aunit.

The column processing portion 13A in the image pickup device ofEmbodiment 1 is identical to the column processing portion 13 describedabove in that the column processing portion 13A includes comparators 31i and 31 i+1, and counters 32 i and 32 i+1 which are each provided so asto correspond to two pixel columns i and i+1, respectively. Also, aSingle Data Rate (SDR) counter in which 1 is added to the leastsignificant digit (1 count) with one period of a clock signal CK as areference for a counting operation of a counter is used as each of thecounters 32 i and 32 i+1. In addition, the configuration and operationof the comparators 31 i and 31 i+1 are also the same as those in thecase of the column processing portion 13 described above.

The comparators 31 i and 31 i+1 compare analog pixel signals Vsig(i) andVsig(i+1) inputted thereto through vertical signal lines 17 i and 17 i+1with reference signals REF each having a RAMP waveform supplied from areference signal generating portion (not shown), respectively. Also, forexample, when the pixel signals Vsig(i) and Vsig(i+1) are each lower inlevel than the reference signal REF, the comparators 31 i and 31 i+1output comparison results Vco(i) and Vco(i+1) each at an “H” level,respectively. On the other hand, when the pixel signals Vsig(i) andVsig(i+1) are each higher in level than the reference signal REF, thecomparators 31 i and 31 i+1 output comparison results Vco(i) andVco(i+1) each at an “L” level, respectively. Here, the comparisonresults Vco(i) and Vco(i+1) each at the “H” level are pulse signalshaving sizes (pulse widths), in a time axis direction, corresponding tothe sizes of the pixel signals Vsig(i) and Vsig(i+1), respectively.

The counters 32 i and 32 i+1 include count portions 321 i and 321 i+1for a first digit (least significant digit), count portions 322 i and322 i+1 for a second digit, count portions 323 i and 323 i+1 for a thirddigit, . . . , respectively.

The column processing portion 13A in Embodiment 1 includes an additioncontrol portion 33 in addition to the comparators 31 i and 31 i+1, andthe counters 32 i and 32 i+1. The addition control portion 33 becomes anoperation state in response to an addition mode signal ADD MODE whichbecomes an active (for example, an “H” level) state in a phase of ahorizontal addition mode in which addition for pixels in a horizontaldirection is carried out. Also, the addition control portion 33 controlsthe counting operations of the count portion 321 i for the first digit,and the count portion 322 i for the second digit each belonging to ani-th column based on the logic of the comparison results Vco(i) andVco(i+1) from the comparators 31 i and 31 i+1, respectively.

With regard to an operation of the column processing portion 13A, let usconsider the case where the comparison results Vco(i) and Vco(i+1) fromthe comparators 31 i and 31 i+1 are each at the “L” level (logic “0”) asshown in FIG. 6. The case means that the addition control portion 33stops the counting operation, of the count portion 321 i for the firstdigit of the counter 32 i belonging to the i-th column, which issynchronized with the clock signal CK, thereby inhibiting the counter 32i belonging to the i-th column from carrying out the counting operation.

When one of the comparison results Vco(i) and Vco(i+1) from thecomparators 31 i and 31 i+1 is at the “H” level (logic “1”), theaddition control portion 33 carries out the following control for a timeperiod of the “H” level. That is to say, the addition control portion 33carries out the control in such a way that the count portion 321 i forthe first digit of the counter 32 i belonging to the i-th column isinstructed to carry out counting one by one with one clock periodsynchronously with the clock signal CK. As a result, a digital valuecorresponding to the size of the pixel signal outputted from the pixelbelonging to one of the pixel column belonging to the i-th row, and thepixel column belonging to the (i+1)-th row is outputted from the counter32 i belonging to the i-th column.

When both the potentials of the comparison results Vco(i) and Vco(i+1)from the comparators 31 i and 31 i+1 are at the “H” level, the additioncontrol portion 33 carries out the following control for a time periodof the “H” level. That is to say, the addition control portion 33carries out the control in such a way that the count portion 322 i forthe second digit of the counter 32 i belonging to the i-th column isinstructed to carry out the counting one by one with one clock periodsynchronously with the clock signal CK. Here, instructing the countportion 322 i for the second digit of the counter 32 i belonging to thei-th column to carry out the counting one by one synchronously with theclock signal CK is identical in sense to instructing the count portion321 i for the first digit to carry out the counting two by twosynchronously with the clock signal CK.

That is to say, when the count portion 321 i for the first digit counts2, the carry is generated and thus the current portion 321 i for thesecond digit counts 1. In addition, the fact that the count portion 321i for the first digit counts 2 means that the two pixel signalsoutputted from the two pixels, belonging to the same row, in both thepixel column belonging to the i-th row, and the pixel column belongingto the (i+1)-th row, that is, the two pixels, exhibiting the same color,adjacent to each other in the horizontal direction are added to eachother.

Therefore, when the potentials of the comparison results Vco(i) andVco(i+1) from the comparators 31 i and 31 i+1 are at the “H” level, adigital value corresponding to a size of a signal obtained by adding thepixel signals from the two pixels adjacent to each other in thehorizontal direction is outputted from the counter 32 i belonging to thei-th column. This results from that under the control of the additioncontrol portion 32, the count portion 322 i for the second digit isinstructed to carry out the counting one by one with one clock periodsynchronously with the clock signal CK for a time period for the “H”level.

Note that, in the phase of the horizontal addition mode, the additioncontrol portion 33 carries out the control under which the countingoperation of the counter, not using the addition for the pixels, of thepaired two counters 32 i and 32 i+1, that is, the counting operations ofthe count portions for the respective digits of the counter 32 i+1 inthe case are stopped. As a result, the power consumption can be saved.

The operation of the column processing portion 13A in Embodiment 1configured as described above is summarized as follows. For example, asshown in FIG. 6, when the pixel signal Vsig(i) belonging to the i-thcolumn is larger in size than the pixel signal Vsig(i+1) belonging tothe (i+1)-th column, in the initial state, both the potentials of thecomparison results Vco(i) and Vco(i+1) from the comparators 31 i and 31i+1 are at the “H” level. For this reason, while the “H” level is held,the count portion 322 i for the second digit carries out the 1-countingoperation (the operation for adding 1) for performing the counting oneby one with one clock period synchronously with the clock signal CK. Asa result, the addition for the pixels is carried out between the twopixels, exhibiting the same color, adjacent to each other in thehorizontal direction. Also, the digital value of the addition for thepixels is outputted from the counter 32 i belonging to the i-th column.

Next, when the level of the reference signal REF having the ramp-likewaveform is reduced to a certain extent, one of the potentials of thecomparison results Vco(i) and Vco(i+1) from the comparators 31 i and 31i+1, that is, the potential of the comparison result Vco(i) from thecomparator 31 i in this case becomes the “L” level. For this reason, fora time period for which the potential of the comparison result Vco(i+1)from the other comparator 31 i+1 is held at the “H” level, the countportion 321 i for the first digit of the counter 32 i belonging to thei-th column carries out the 1-counting operation with one clock periodsynchronously with the clock signal CK. At this time, no addition forthe pixels is carried out, and the digital value corresponding to thesize of the pixel signal from the pixel belonging to the (i+1)-th columnis outputted from the counter 32 i belonging to the i-th column.

When the level of the reference signal REF having the ramp-like waveformis further reduced, and both thus the potentials of the comparisonresults Vco(i) and Vco(i+1) from the comparators 31 i and 31 i+1 eachbecome the “L” level, no counting operation in the counter 32 ibelonging to the i-th column is carried out.

The above operation is carried out for both a dark signal when nophotoelectric conversion is carried out in each of the pixels 20 in thepixel array portion 11, and a luminance signal when the photoelectricconversion is carried out in each of the pixels 20 in the pixel arrayportion 11.

FIG. 7 shows a color filter arrangement in the pixel array portion 11.The column processing portion 13A in Embodiment 1 is used for the Bayerarrangement about Red (R), Green (G) and Blue (B). As a result, this ishow the addition for the pixels in the horizontal direction can becarried out with respect to the pixels exhibiting the same color andbelonging to the same row. The addition for the pixels is carried outbetween the dark signals and the luminance signals from a pixel B22 anda pixel B42, between the dark signals and the luminance signals from apixel B24 and a pixel B44, and so on.

It is noted that for the Bayer arrangement shown in FIG. 7, one ADconversion circuit including the comparator 31 and the counter 32 isprovided every adjacent two pixel columns as a unit. Also, the pixelsignal is selectively inputted from one of the adjacent two pixelcolumns to the comparator 31 through a change-over switch (not shown).

As has been described, when in the phase of the horizontal additionmode, both the comparison results Vco(i) and Vco(i+1) from thecomparators 31 i and 31 i+1 are at the “H” level, the count portion 322i for the second digit is instructed to carry out the 1-countingoperation with one clock period, thereby making it possible to obtainthe following effect. That is to say, since the addition for the twopixels in the horizontal direction can be realized within the columnprocessing portion 13A, an amount of information horizontally outputtedcan be reduced by one half while the sensitivity is maintained. As aresult, it is possible to realize the enhancement of the frame rate, andthe reduction of the power consumption.

In addition thereto, since in the phase of the horizontal addition mode,the counting operation of the counter not used in the addition for thepixels is stopped, it is possible to further reduce the powerconsumption. In addition, the luminance signal information and the darksignal information, on the pixel B22 and the pixel B42, horizontallyadded to each other by utilizing the technique about the columnprocessing portion 13A in Embodiment 1, and the luminance signalinformation and the dark signal information, on the pixel B24 and thepixel B44 can be vertically added to each other by utilizing the relatedtechnique (for example, the technique disclosed in Patent Document 1).As a result, since it is possible to realize the addition for the twopixels in both the horizontal and vertical directions, it is possible tofurther enhance the frame rate.

It is noted that in Embodiment 1, the first logic is set as the “H”level, and the second logic is set as the “L” level. Also, when thepixel signals Vsig(i) and Vsig(i+1) are each lower in level than thereference signal REF, the comparators 31 i and 31 i+1 output thecomparison results Vco(i) and Vco(i+1) each at the “H” level, and whenthe pixel signals Vsig(i) and Vsig(i+1) are each higher in level thanthe reference signal REF, the comparators 31 i and 31 i+1 output thecomparison results Vco(i) and Vco(i+1) each at the “L” level. However,this logic may be inverted. That is to say, a configuration may also beadopted such that when the pixel signals Vsig(i) and Vsig(i+1) are eachlower in level than the reference signal REF, the comparators 31 i and31 i+1 output the comparison results Vco(i) and Vco(i+1) each at the “L”level (first logic), and when the pixel signals Vsig(i) and Vsig(i+1)are each higher in level than the reference signal REF, the comparators31 i and 31 i+1 output the comparison results Vco(i) and Vco(i+1) eachat the “H” level (second logic).

In this case, when both the potentials of the comparison results Vco(i)and Vco(i+1) from the comparators 31 i and 31 i+1 are at the “L” level,while the “L” level is held, the count portion 322 i for the seconddigit carries out the operation for counting 1 with one clock periodsynchronously with the clock signal CK. On the other hand, when both thepotentials of the comparison results Vco(i) and Vco(i+1) from thecomparators 31 i and 31 i+1 are at the “H” level, the counting operationof the counter 32 i belonging to the i-th column may be stopped.

Change of Embodiment 1

In Embodiment 1, the addition for the two pixels exhibiting the samecolor and belonging to the same row in the horizontal direction iscarried out with the two pixel columns i and i+1 as the unit. However,with regard to Change of Embodiment 1, a configuration can also beadopted such that the addition for the two pixels of the three pixelsexhibiting the same color and belonging to the same row in thehorizontal direction is carried out with the three pixel columns i−1, iand i+1 as a unit.

The addition for the two pixels of the three pixels exhibiting the samecolor and belonging to the same row in the horizontal direction iscarried out by utilizing the technique of Embodiment 1, whereby theamount of information horizontally outputted can be halved while thesensitivity is maintained as compared with the case of the addition forthe two pixels of the three pixels exhibiting the same color andbelonging to the same row in the horizontal direction is carried outwithout utilizing the technique of Embodiment 1. Therefore, it ispossible to realize the enhancement of the frame rate, and the reductionof the power consumption. In addition, the addition for the pixels inthe vertical directions can also be carried out similarly to the case ofEmbodiment 1 by utilizing the technique of Embodiment 1 combined withthe related technique (for example, the technique disclosed in PatentDocument 1).

When the configuration of the column processing portion 13A′ in Changeis adopted, in the phase of a horizontal addition mode, only the countportions for the respective digits of the counter 32 i belonging to thei-th column are operated, and the counting operations of the counters 32i-1 and 32 i+1 belonging to the remaining two pixel columns i−1 and i+1are stopped. By carrying out this operation, it is possible to furtherreduce the power consumption.

In addition, it is also expected to adopt a method in which the additionfor the two pixels of the three pixels exhibiting the same color andbelonging to the same row is carried out, the normal AD conversion iscarried out for one pixel belonging to the (i−1)-th column and having norelation to the addition in the counting operation of the counter 32i-1, and after completion of the horizontal output, the addition iscarried out in the digital signal processing portion. In this case, theamount of information horizontally outputted can be reduced two-thirdswhile the sensitivity is maintained as compared with the case where thefull addition for the (3.times.3) pixels in the horizontal and verticaldirections is carried out. Therefore, it is possible to anticipate acertain degree of enhancement of the frame rate.

Embodiment 2

FIG. 9 is a block diagram, partly in circuit, showing a configuration ofa column processing portion 13B in an image pickup device according toEmbodiment 2 of the present invention. In the figure, the same portionsas those in FIG. 3 are designated with the same reference numerals orsymbols, respectively. In this case, three pixel columns are set as aunit, and a circuit configuration of three pixel columns of an (i−1)-thcolumn, an i-th column and an (i+1)-th column is shown.

The column processing portion 13B in the image pickup device ofEmbodiment 2 includes comparators 31 i-1, 31 i and 31 i+1, and counters32 i-1, 32 i and 32 i+1 which are each provided so as to correspond tothe three pixel columns i−1, i and i+1, respectively. Also, the additionfor the three pixels of the three pixels exhibiting the same color andbelonging to the same row in the horizontal direction is realized. Inthe column processing portion 13B as well, the SDR counter is used aseach of the counters 32 i-1, 32 i and 32 i+1. In addition, theconfigurations and operations of the comparators 31 i and 31 i+1 arealso the same as those in the column processing portion 13A previouslystated.

Since in the case of the column processing portion 13A in Embodiment 1,the addition for the two pixels in the horizontal direction is carriedout, the count portion 322 i for the second digit unconditionally counts1 irrespective of the count value in the count portion 321 i for thefirst digit, thereby making it possible to realize the addition for thetwo pixels. On the other hand, whether or not each of the count portions321 i to 323 i for the first to third digits needs to count 1 (additionof 1) changes depending on the count portions 321 i and 322 i for thefirst and second digits.

In the light of the foregoing, the following control is carried out inthe column processing portion 13B in Embodiment 2. An addition controlportion 33 receives as inputs thereof comparison results Vco(i−1),Vco(i) and Vco(i+1) from the comparators 31 i-1, 31 i and 31 i+1corresponding to the three pixels exhibiting the same color andbelonging to the same row, respectively, and values R1 and R2 in thecount portions 321 i and 322 i for the first and second digits. Also,the addition control portion 33 controls whether or not the operationfor counting 1 is carried out in each of the count portions 321 i to 323i for the first to third digits synchronously with the clock signal CKbased on the comparison results Vco(i−1), Vco(i) and Vco(i+1), and thevalues R1 and R2.

FIGS. 10A to 10C respectively show relationships between the comparisonresults Vco(i−1), Vco(i) and Vco(i+1) from the comparators 31 i-1, 31 iand 31 i+1, and the values R1 and R2 in the count portions 321 i and 322i, and the control for the count portions 321 i to 323 i for the firstto third digits.

Specifically, FIG. 10A shows a change in value in the count portion 321i for the first digit, FIG. 10B shows a change in value in the countportion 322 i for the second digit, and FIG. 10C shows a change in valuein the count portion 323 i for the third digit. It is noted that inFIGS. 10A to 10C, for each of the comparison results Vco(i−1), Vco(i)and Vco(i+1), and the values R1 and R2 in the count portions 321 i and322 i, the “L” level is described as the logic “0,” and the “H” level isdescribed as the logic “1.”

(A) With Regard to Count Portion 321 i for First Digit

When the logics of the comparison results Vco(i−1), Vco(i) and Vco(i+1)are “000,” “110,” “011” or “101,” the counting operation is inhibitedirrespective of the values R1 and R2 of the count portions 321 i and 322i. When the logics of the comparison results Vco(i−1), Vco(i) andVco(i+1) are “100,” “010,” “111” or “001,” the 1-counting operation iscarried out with one clock period synchronously with the clock signal CKirrespective of the values R1 and R2 in the count portions 321 i and 322i.

(B) With Regard to Count Portion 322 i for Second Digit

When the logics of the comparison results Vco(i−1), Vco(i) and Vco(i+1)are “000,” the counting operation is inhibited irrespective of thevalues R1 and R2 in the count portions 321 i and 322 i. When the logicsof the comparison results Vco(i−1), Vco(i) and Vco(i+1) are “110,” “011”or “101,” the 1-counting operation is carried out with one clock periodsynchronously with the clock signal CK irrespective of the values R1 andR2 in the count portions 321 i and 322 i.

Also, when the logics of the comparison results Vco(i−1), Vco(i) andVco(i+1) are “100,” “010” or “001,” the counting operation is inhibitedwhen the values R1 and R2 in the count portions 321 i and 322 i are “00”or “01,” and the 1-counting operation is carried out when the values R1and R2 in the count portions 321 i and 322 i are “10” or “11.” Moreover,when the logics of the comparison results Vco(i−1), Vco(i) and Vco(i+1)are “111,” the counting operation is inhibited when the values R1 and R2in the count portions 321 i and 322 i are “10” or “11,” and the1-counting operation is carried out when the values R1 and R2 in thecount portions 321 i and 322 i are “00” or “01.”

(C) With Regard to Count Portion 323 i for Third Digit

When the logics of the comparison results Vco(i−1), Vco(i) and Vco(i+1)are “000,” the counting operation is inhibited irrespective of thevalues R1 and R2 in the count portions 321 i and 322 i. Also, when thelogics of the comparison results Vco(i−1), Vco(i) and Vco(i+1) are“100,” “010” or “001,” the counting operation is inhibited when thevalues R1 and R2 in the count portions 321 i and 322 i are “00,” “10” or“01,” and the 1-counting operation is carried out when the values R1 andR2 in the count portions 321 i and 322 i are “11.”

In addition, when the logics of the comparison results Vco(i−1), Vco(i)and Vco(i+1) are “110,” “011” or “101,” the counting operation isinhibited when the values R1 and R2 in the count portions 321 i and 322i are “00” or “10,” and the 1-counting operation is carried out when thevalues R1 and R2 in the count portions 321 i and 322 i are “11” or “01.”Moreover, when the logics of the comparison results Vco(i−1), Vco(i) andVco(i+1) are “111,” the counting operation is inhibited when the valuesR1 and R2 in the count portions 321 i and 322 i are “00,” and the1-counting operation is carried out when the values R1 and R2 in thecount portions 321 i and 322 i are “10,” “11” or “01.”

It should be noted that when in the phase of the horizontal additionmode, the control is carried out under which the counting operation ofthe counter(s), not used in the addition for the pixels, of a set ofthree counters 32 i-1, 32 i and 32 i+1 is stopped, it is possible torealize the low power consumption. In the case of Embodiment 2, thecontrol may be carried out under which the counting operations of thecount portions for the respective digits in the counters 32 i-1 and 32i+1 are stopped.

Here, when the addition centers are set at given intervals in the Bayerarrangement shown in FIG. 11, the processing in a semiconductor DigitalSignal Processor (DSP) for the signal processing becomes simple. Fromthis reason, the addition centers are preferably set at the givenintervals because in the addition for the three pixels, a color of arepresentative coordinate point of a final image, and an original colorare identical to each other. By the way, in the case of the addition forthe two pixels, a color of a representative coordinate point of a finalimage, and an original color are different from each other.

In the Bayer arrangement shown in FIG. 11, the addition for the threepixels in the horizontal direction is carried out in such a way that thepixel signals from a pixel B44, a pixel B64 and a pixel B84 are added toone another, next, the pixel signals from a pixel R11, a pixel R31 and apixel R51 are added to one another, and so forth. By carrying out theaddition for the three pixels, the addition centers in the horizontaldirection (the pixel B64 and the pixel B31 are both the addition centersin this case) can be set at the given intervals of the three pixels.

It is noted that for the Bayer arrangement shown in FIG. 11, one ADconversion circuit including the comparator 31 and the counter 32 isprovided every adjacent two pixel columns as a unit similarly to thecase of Embodiment 1. Also, one of the signals from the adjacent twopixel columns is selectively inputted to the comparator 31 through achange-over switch (not shown).

At this time, in carrying out the addition for the pixels with theaddition centers in the horizontal direction being set at the given ofthe three pixels, the following procedure may be adopted. That is tosay, four AD conversion circuits i−2, i−1, i, and i+1 corresponding tothe adjacent eight pixel columns are set as a unit. Also, when the pixelsignal is read out from the pixel corresponding to Red (R), the three ADconversion circuits i−2, i−1 and i on one side may be used. When thepixel signal is read out from the pixel corresponding to Blue (B), thethree AD conversion circuits i−1, i and i+1 on the other side may beused.

In addition, the column processing portion 13B in Embodiment 2 is usedfor the Bayer arrangement shown in FIG. 11, whereby the addition for thethree pixels in the horizontal direction can be carried out with respectto the pixels exhibiting the same color and belonging to the same row.Specifically, the addition for the three pixels is carried out among thedark signals and the luminance signals from the pixel B44, the pixelB64, and the pixel B84. Next, the addition for the three pixels iscarried out among the dark signals and the luminance signals from thepixel B46, the pixel B66, and the pixel B86. Next, the addition for thethree pixels is carried out among the dark signals and the luminancesignals from the pixel B48, the pixel B68, and the pixel B88. Afterthat, similarly, the addition for the three pixels in the horizontaldirection is carried out with respect to the pixels exhibiting the samecolor and belonging to the same row.

As has been described, the comparison results Vco(i−1), Vco(i) andVco(i+1) from the comparators 31 i-1, 31 i and 31 i+1, and the values R1and R2 in the count portions 321 i and 322 i for the first and seconddigits of the counter 32 i are used in the phase of the horizontaladdition mode. Also, the control relating to whether or not the1-counting operation is carried out (1 is added) with one clock periodsynchronously with the clock signal CK in each of the count portions 321i to 323 i for the first to third digits based on the comparison resultsVco(i−1), Vco(i) and Vco(i+1), and the values R1 and R2, thereby makingit possible to obtain the following effect. That is to say, the additionfor the three pixels in the horizontal direction can be realized withinthe column processing portion 13B, whereby the amount of informationhorizontally outputted can be reduced to one-third while the sensitivityis maintained. Therefore, it is possible to realize the enhancement ofthe frame rate, and the reduction of the power consumption.

In addition, since the counting operation of the counter(s) not used inthe addition for the pixels is stopped in the phase of the horizontaladdition mode, it is possible to further reduce the power consumption.Further, a plurality piece of luminance signal information and aplurality piece of dark signal information which are horizontally addedto one another by utilizing the technique about the column processingportion 13B in Embodiment 2 can also be vertically added to one anotherby utilizing the related technique (for example, the technique disclosedin Patent Document 1). Specifically, three pieces of luminance signalinformation and three pieces of dark signal information from the pixelB44, the pixel B64, and the pixel B84, three pieces of luminance signalinformation and three pieces of dark signal information from the pixelB46, the pixel B66, and the pixel B86, and three pieces of luminancesignal information and three pieces of dark signal information from thepixel B48, the pixel B68, and the pixel B88 are vertically added to oneanother. As a result, since it is possible to realize the addition forthe three pixels in both the horizontal and vertical directions, it ispossible to realize the further enhancement of the frame rate.

Note that, when the pixel signals Vsig(i−1), Vsig(i) and Vsig(i+1) areeach lower in level than the reference signal REF, the comparators 31i-1, 31 i and 31 i+1 output the comparison results Vco(i−1), Vco(i) andVco(i+1) each at the “H” level, and when the pixel signals Vsig(i−1),Vsig(i) and Vsig(i+1) are each higher in level than the reference signalREF, the comparators 31 i-1, 31 i and 31 i+1 output the comparisonresults Vco(i−1), Vco(i) and Vco(i+1) each at the “L” level. However,this logic may be inverted. That is to say, a configuration may also beadopted such that when the pixel signals Vsig(i−1), Vsig(i) andVsig(i+1) are each higher in level than the reference signal REF, thecomparators 31 i-1, 31 i and 31 i+1 output the comparison resultsVco(i−1), Vco(i) and Vco(i+1) each at the “H” level, and when the pixelsignals Vsig(i−1), Vsig(i) and Vsig(i+1) are each lower in level thanthe reference signal REF, the comparators 31 i-1, 31 i and 31 i+1 outputthe comparison results Vco(i−1), Vco(i) and Vco(i+1) each at the “L”level.

In addition, in Embodiment 2, the three comparators 31 i-1, 31 i and 31i+1, and the three counters 32 i-1, 32 i and 32 i+1 which eachcorrespond to the three pixel columns, respectively, are set as theunit. Also, the control relating to whether or not 1 is added to each ofthe first to third digits of one counter 32 i is carried out based onthe comparison results Vco(i−1), Vco(i) and Vco(i+1) from the threecomparators 31 i-1, 31 i and 31 i+1, and the values of the first andsecond digits of the one counter 32 i of the three counters 32 i-1, 32 iand 32 i+1. However, the present invention is by no means limited to thecase where the three pixel columns are set as the unit. That is to say,the present invention may also be applied to the case where the four ormore pixel columns are set as a unit basically in accordance with thesame concept as that in the case of the three pixel columns are set asthe unit.

Embodiment 3

FIG. 12 is a block diagram, partly in circuit, showing a configurationof a column processing portion 13C in an image pickup device accordingto Embodiment 3 of the present invention. In the figure, the sameportions as those in FIG. 3 are designated with the same referencenumerals or symbols. In this case, a circuit configuration of two pixelcolumns, i.e., an i-th column, and an (i+1)-th column is shown.

The column processing portion 13C in Embodiment 3 is identical inconfiguration to the column processing portion 13A in Embodiment 1 inthat the column processing portion 13C includes comparators 31 i and 31i+1, and the counter 32 i and 32 i+1 which are each provided so as tocorrespond to the two pixel columns i, and i+1, respectively.Hereinafter, the pixel column i, and the pixel column i+1 will bereferred to as an even-numbered column, and an odd-numbered column,respectively, in some cases.

In the column processing portion 13A in Embodiment 1, the SDR counter inwhich 1 is added (1 is counted) to the least significant digit with theone period of the clock signal CK is used as each of the counters 32 iand 32 i+1. On the other hand, in the column processing portion 13C inEmbodiment 3, a Double Data Rate (DDR) counter in which 1 is added tothe least significant digit with a one half period of the clock signalCK is used as each of the counters 32 i and 32 i+1. Use of the DDRcounter offers an advantage that the same AD conversion operation can berealized at a speed corresponding to the clock period which is half thatof the clock signal CK period as compared with the case of use of theSDR counter.

Also, the feature of the column processing portion 13C in Embodiment 3is that the counter 32 i carries out the following operation under thecontrol by the addition control portion 33. That is to say, when in thecounter 32 i, both potentials of comparison results Vco(i) and Vco(i+1)from the two comparators 31 i and 31 i+1 are at the “H” level, a countportion 322 i for a second digit carries out a 1-counting operation withone half clock period synchronously with the clock signal CK. Inaddition, when one of the potentials of the comparison results Vco(i)and Vco(i+1) from the two comparators 31 i and 31 i+1 is at the “H”level, the count portion 322 i for the second digit carries out the1-counting operation with one clock period synchronously with the clocksignal CK. Also, when both the potentials of the comparison resultsVco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 are at the“L” level, the count portion 322 i for the second digit carries out nocounting operation.

It is noted that FIG. 12 merely simplifies the concept of the columnprocessing portion 13C in Embodiment 3 in the form of the block diagram.

<LSB Circuit Belonging to Even-Numbered Column>

FIG. 13 is a block diagram showing a concrete circuit configuration of aLeast Significant Bit (LSB) count portion (an LSB circuit belonging toan even-numbered column) 321 i. The LSB count portion 321 i inEmbodiment 3 includes latches 40, 41 and 42, a firstnon-inverting/inverting circuit 43, inverters 44 and 45, a secondnon-inverting/inverting circuit 46, and an up/down control portion 47.

The latch circuit 40 latches therein the clock signal CK in response toa control signal COB0 supplied from the addition control portion 33. Thelatch circuit 41 latches therein the clock signal CK in response to acontrol signal COB1 supplied from the addition control portion 33. Theclock signal CK latched in the latch circuit 40 is supplied to an inputnode LT of the first non-inverting/inverting circuit 43. The clocksignal CK latched in the latch circuit 41 is supplied in the form of acontrol signal aff, and an inverting control signal affx obtainedthrough inversion in the inverter 45 to the firstnon-inverting/inverting circuit 43.

Here, a concrete configuration of the addition control portion 33 willbe described. The addition control portion 33 includes an OR circuit 331and an AND circuit 332. The OR circuit 331 receives as two inputsthereof the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1. When at least one of the potentials of thecomparison results Vco(i) and Vco(i+1) is at the “H” level, the ORcircuit 331 outputs the control signal COB0. The AND circuit 332receives as two inputs thereof the comparison results Vco(i) andVco(i+1) from the two comparators 31 i and 31 i+1. When at least one ofthe potentials of the comparison results Vco(i) and Vco(i+1) is at the“H” level, the AND circuit 332 outputs the control signal COB1.

As a result, when at least one of the potentials of the comparisonresults Vco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 isat the “H” level, the latch circuit 40 latches therein the clock signalCK in response to the control signal COB0 outputted from the OR circuit331. When both the potentials of the comparison results Vco(i) andVco(i+1) from the two comparators 31 i and 31 i+1 are at the “H” level,the latch circuit 41 latches therein the clock signal CK in response tothe control signal COB1 outputted from the AND circuit 332.

The first non-inverting/inverting circuit 43 carries out the controlrelating to whether the clock signal CK after having been latched in thelatch circuit 40 should be transferred (non-inverting-transferred) witha polarity of the clock signal CK being held as it is (non-inverting),or is transferred (inverting-transferred) with the polarity of the clocksignal CK being inverted. This control is carried out in accordance withthe control signal aff and the inverting control signal affx suppliedfrom the latch circuit 41.

FIGS. 14A and 14B show changes in potential at the input node LT of thefirst inverting/non-inverting circuit 43, the potential of the invertingcontrol signal affx, and the potential at the output node FO of thefirst inverting/non-inverting circuit 43.

A timing waveform chart shown in FIG. 14A is different from that shownin FIG. 14B in timing when the logic state transits from a state inwhich both the potentials of the comparison results Vco(i) and Vco(i+1)from the two comparators 31 i and 31 i+1 are each at the “H” level to astate in which one of the potentials of the comparison results Vco(i)and Vco(i+1) from the two comparators 31 i and 31 i+1 is at the “H”level. Specifically, the timing shown in FIG. 14B is shifted from thetiming shown in FIG. 14A by one half clock of the clock signal CKsupplied to the input node LT.

Here, the value (the “H” level or the “L” level) at the output node FOwhen both the potentials of the comparison results Vco(i) and Vco(i+1)from the two comparators 31 i and 31 i+1 are at the “L” level becomesthe final count result in the LSB count portion 321 i. The fact that thetiming when the logic state transits from the state in which both thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 are at the “H” level to the state in whichone of the potentials of the comparison results Vco(i) and Vco(i+1) fromthe two comparators 31 i and 31 i+1 is at the “H” level is shifted byone half clock period means that the count value is different betweenthese logic states by “1.”

When both the potentials of the comparison results Vco(i) and Vco(i+1)from the two comparators 31 i and 31 i+1 are at the “H” level in FIG.14A, the inverting control signal affx is a clock signal which is inphase with the clock signal CK supplied to the input node LT. Also, thefirst non-inverting/inverting circuit 43 non-inverting-transfers theclock signal CK at the “L” level at the input node LT, andinverting-transfers the clock signal CK at the “H” level at the inputnode LT under the control made in accordance with the control signal affand the inverting control signal affx. As a result, the potential at theoutput node FO is usually held at the “L” level.

When one of the potentials of the two comparison results Vco(i) andVco(i+1) is at the “H” level, the “L” level of the inverting controlsignal affx in the phase of the transition from the logic state in whichboth the potentials of the comparison results Vco(i) and Vco(i+1) are atthe “H” level is held as it is. Also, the first non-inverting/invertingcircuit 43 usually carries out the non-inverting transfer under thecontrol mode in accordance with the control signal aff and the invertingcontrol signal affx. As a result, the clock signal CK supplied to theinput node LT is transmitted to the output node FO as it is.

When both the potentials of the two comparison results Vco(i) andVco(i+1) are at the “L” level, the “L” level of the inverting controlsignal affx in the phase of the transition from the logic state in whichone of the potentials of the two comparison results Vco(i) and Vco(i+1)is at the “H” level is held as it is. Also, the firstnon-inverting/inverting circuit 43 usually carries out the non-invertingtransfer under the control made in accordance with the control signalaff and the inverting control signal affx. As a result, the “L” level ofthe clock signal CK at the input node LT is transmitted to the outputnode FO as it is.

It should be noted that although the case where the potential at theinput node LT is fixed to the “L” level when the logic state transitsfrom the state in which one of the potentials of the two comparisonresults Vco(i) and Vco(i+1) is at the “H” level to the state in whichboth the potentials of the two comparison results Vco(i) and Vco(i+1)are at the “L” level is given as the example in this case, the potentialat the input node LT may be fixed to the “H” level. In this case, thepotential of the “H” level at the input node LT is transmitted to theoutput node FO as it is.

When one of the potentials of the two comparison results Vco(i) andVco(i+1) is at the “H” level, the “H” level of the inverting controlsignal affx in the phase of the transition from the logic state in whichboth the potentials of the two comparison results Vco(i) and Vco(i+1)are at the “H” level is held as it is. Also, the firstnon-inverting/inverting circuit 43 usually carries out the non-invertingtransfer under the control made in accordance with the control signalaff and the inverting control signal affx. As a result, the polarity ofthe clock signal CK at the input node LT is inverted, and the resultingsignal is transmitted to the output node FO.

When both the potentials of the two comparison results Vco(i) andVco(i+1) are at the “L” level, the “H” level of the inverting controlsignal affx in the phase of the transition from the logic state in whichone of the potentials of the two comparison results Vco(i) and Vco(i+1)are at the “H” level is held as it is. Also, the firstnon-inverting/inverting circuit 43 usually carries out the invertingtransfer under the control made in accordance with the control signalaff and the inverting control signal affx. As a result, the “L” level ofthe potential at the input node LT is inverted, and the resulting signalis transmitted to the output node FO.

It should be noted that although the case where the potential at theinput node LT is fixed to the “L” level when the logic state transitsfrom the state in which one of the potentials of the two comparisonresults Vco(i) and Vco(i+1) is at the “H” level to the state in whichboth the potentials of the two comparison results Vco(i) and Vco(i+1)are at the “L” level is given as the example in this case, the potentialat the input node LT may be fixed to the “H” level. In this case, the“H” level of the potential at the input node LT is inverted, and theresulting signal at the “L” level is transmitted to the input node FO.

The second non-inverting/inverting circuit 46 carries out the controlrelating to whether the clock signal CK which isnon-inverting-transferred or inverting-transferred in polarity thereofin the first non-inverting/inverting circuit 43, and is then inverted inthe converter 44 should be non-inverting-transferred orinverting-transferred again. This control is carried out based on thecontents latched in the latch circuit 42. The latch circuit 42 holds thelogic state (the “H” level or the “L” level) of the potential at thenode PD on the output side of the second non-inverting/inverting circuit45 when a potential of a control signal FLIPLSB changes from the “L”level to the “H” level while the potential of the control signal FLIPLSBchanges in the order of the “L” level.fwdarw.the “H” level.fwdarw.the“L” level. The control signal FLIPLSB is a signal in accordance withwhich the latch circuit 42 and a latch circuit 621 (refer to FIG. 16)which will be described later are each controlled, and is generated inthe system control portion 15 shown in FIG. 1.

The counter 32 i counts each of the dark signal and the luminancesignal. At this time, the logic state in the phase of the end of thecounting is latched with respect to the dark signal in accordance withthe control signal FLIPLSB. Also, whether the counting of the luminancesignal should be started at the transition of the clock signal CK fromthe “L” level to the “H” level or at the transition of the clock signalCK from the “H” level to the “L” level is controlled in accordance withthe control signal FLIPLSB. Here, the control signal FLIPLSB determinesthe timing of latching the logic state. Therefore, the control signalFLIPLSB changes as an example in the order of the “L” level.fwdarw.the“H” level.fwdarw.the “L” level before the luminance signal is countedafter the counting of the dark signal has been completed.

As a result, the second non-inverting/inverting circuit 46 controlswhether the clock signal CK inputted thereto through the inverter 44should be non-inverting-transferred or inverting-transferred when thepotential of the control signal FLIPLSB changes from the “L” level tothe “H” level and then changes from the “H” level to the “L” level,i.e., becomes the “L” level again.

When the potential at the node PD is held at the “H” level in a state inwhich the dark signal outputted from the pixel 20 without beingphotoelectrically converted has been done with the AD conversion basedon the operation of the second non-inverting/inverting circuit 46, thecontrol can be carried out so that the potential at the node PD startswith the change of the “H” level to the “L” level. In addition, when thepotential at the node PD is at the “L” level in a state in which thedark signal has been done with the AD conversion, the control can becarried out so that the potential at the node PD starts with the changeof the “L” level to the “H” level.

The up/down control portion 47 carries out the control relating towhether up-count or down-count should be carried out. An output COUT,from the up/down control portion 47, as an output from the count portion321 i for the first digit is transmitted to the count portion 322 i forthe second digit.

<Count Portion for Second Digit>

FIG. 15 is a block diagram, partly in circuit, showing a circuitconfiguration of the count portion 322 i for the second digit belongingto the pixel column i. The count portion 322 i for the second digitbelonging to the pixel column i includes Flip-Flops (FF) 51 and 52 whichare connected to each other in a two-stage cascade form, an up/downcontrol portion 53, and a holding portion 54 for holding thereincontents of the counter. Also, the count portion 322 i for the seconddigit receives as an input CIN thereof an output COUT from the countportion 321 i for the first digit. The input CIN is inverted in polaritythereof by an inverter 55, and is supplied as a negative-phase-sequenceclock signal xck to the flip-flop 51. Also, the inverted input isfurther inverted in polarity thereof by an inverter 56, and is suppliedas a positive-phase-sequence clock signal ck to the flip-flop 52.

Storage states of the flip-flops 51 and 52 can be controlled from theoutside in accordance with control signals RHA and XRLA inputted to SETterminals, and control signals RHB and XRLB inputted to RESET terminals,respectively. The up/down control portion 53 controls whether theup-count or the down-count should be carried out. Here, an up-count modeis used in AD-converting the luminance signal, and a down-count mode isused in AD-converting the dark signal.

The holding portion 54 holds therein the storage contents of the counterbased on the operations of the flip-flops 51 and 52 when the up-countand the down-count are switched over each other. When the up-count andthe down-count are switched over each other, the potential of thecontrol signal CTHLD is set at the “H” level, and the potential of thecontrol signal xCTHLD is set at the “L” level in order to prevent thestorage contents of the counter from being changed.

The positive-phase-sequence clock ck and the negative-phase-sequenceclock xck which are generated based on the input CIN are inputtedtogether with the comparison result Vco(i) from the comparator 31 ibelonging to the even-numbered column i to a control clock generatingportion 57. The control clock generating portion 57 generates controlpulses CG1 and CG2, and inverting control pulses XCG1 and XCG2 obtainedby inverting the polarities of the control pulses CG1 and CG2,respectively, in accordance with the logics of the control signal COB1outputted from the AND circuit 332 of the addition control portion 33,and the positive-phase-sequence clock signal ck and thenegative-phase-sequence clock signal xck.

Specifically, when the potentials of the negative-phase-sequence clocksignal xck and the control signal COB1 are at the “H” level, thepotential of the control pulse CG1 is set as the “H” level, and thepotential of the inverting control pulse XCG1 is set at the “L” level.In any case other than the above case, the potential of the controlpulse CG1 is set as the “L” level, and the potential of the invertingcontrol pulse XCG1 is set at the “H” level. In addition, when both thepotentials of the positive-phase-sequence clock signal ck and thecontrol signal COB1 are at the “H” level, the potential of the controlpulse CG2 is set as the “H” level, and the potential of the invertingcontrol pulse XCG2 is set as the “L” level. In any case other than theabove case, the potential of the control pulse CG2 is set as the “L”level, and the potential of the inverting control pulse XCG2 is set atthe “H” level. The control pulse CG1 and the inverting control pulseXCG1, and the control pulse CG2 and the inverting control pulse XCG2 areall supplied to an FF control portion 58.

The FF control portion 58 generates the control signals RHA, XRLA, andcontrol signals RHB, XRLB described above based on the control pulse CG1and the inverting control pulse XCG1, and the control pulse CG2 and theinverting control pulse XCG2, respectively, thereby controlling thestorage states of the flip-flops 51 and 52 from the outside.Specifically, when the potential of the control pulse CG1 is at the “H”level, and the potential of the control pulse XCG1 is at the “L” level,a value LSB2IN of the count portion 321 i+1 for the first digitbelonging to the odd-numbered column i+1 is outputted as each of thecontrol signals RHA and XRLA. In addition, when the potential of thecontrol pulse CG1 is at the “L” level, and the potential of the controlpulse XCG1 is at the “H” level, the control signals RH and XRL which aresupplied from the outside are outputted as the control signals RHA andXRLA, respectively.

When the potential of the control pulse CG2 is at the “H” level, and thepotential of the control pulse XCG2 is at the “L” level, a value LSB2INof the count portion 321 i+1 for the first digit belonging to theodd-numbered column i+1 is outputted as each of the control signals RHBand XRLB. In addition, when the potential of the control pulse CG2 is atthe “L” level, and the potential of the control pulse XCG2 is at the “H”level, the control signals RH and XRL which are supplied from theoutside are outputted as the control signals RHB and XRLB, respectively.

Here, for a time period for which at least one of the potentials of thecomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 is at the “L” level, of the phase of the horizontal non-additionmode and the phase of the horizontal addition mode, the control signalRH is outputted as each of the control signals RHA and RHB. In addition,the control signal XRL is outputted as each of the control signals XRLAand XRLB. In this state, the logic states of the flip-flops 51 and 52can be initialized in accordance with the control signals RH and XRLsupplied from the outside.

Both the potentials of the control signals RH and XRL are set at the “H”level, whereby both the potentials at the output nodes sla1 and msa1 ofthe flip-flops 51 and 52 can be initialized at the “L” level. Inaddition, both the potentials of the control signals RH and XRL are setat the “L” level, whereby both the potentials at the output nodes sla1and msa1 of the flip-flops 51 and 52 can be initialized at the “H”level. In a phase of a normal operation different from the initializingoperation, the potential of the control signal RH is used as “L” level,and the potential of the control signal XRL is used as “H” level.

For the time period for which at least one of the potentials of thecomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 is at the “L” level of the phase of the horizontal non-additionmode and the phase of the horizontal addition mode, the potential of thecontrol signal RH is set as the “L” level, and the potential of thecontrol signal XRL is set as the “H” level. As a result, the countportion 322 i for the second digit of the normal counter 32 i operatesso as to receive as the input CIN thereof the output COUT from the countportion 321 i for the first digit. Therefore, the count portion 321 ifor the first digit operates so as to add 1 to the count portion for thesecond digit of the counter every one clock period when one of thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 is at the “H” level in the phase of thehorizontal addition mode (1-counting operation).

In addition, when both the potentials of the comparison results Vco(i)and Vco(i+1) from the two comparators 31 i and 31 i+1 are at the “L”level, the potential of the input CIN is fixed to either the “H” levelor the “L” level. Therefore, the count portion 321 i for the first digitoperates so as not to add 1 to the count portion for the second digit ofthe counter when both the potentials of the comparison results Vco(i)and Vco(i+1) from the two comparators 31 i and 31 i+1 are at the “L”level in the phase of the horizontal addition mode.

For a time period, for which both the potentials of the comparisonresults Vco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 areheld at the “H” level, of the phase of the horizontal addition mode, theoperation is carried out as follows. When the potential of thenegative-phase-sequence clock signal xck is at the “H” level, and thepotential of the positive-phase-sequence clock signal ck is at the “L”level, the value LSB2IN of the count portion 321 i+1 for the first digitbelonging to the odd-numbered column i+1 is outputted as each of thecontrol signals RHA and XRLA. Also, an inverted value of the valueLSB2IN is substituted (set) into the output node sla1 of the flip-flop51. As a result, the potential at the inner node sla0 of the flip-flop51 can be rewritten and is inverted in logic thereof in the order ofsla1.fwdarw.msa0.fwdarw.msa1.fwdarw.din to be transferred. Also, thepotentials at the nodes msa0, msa1, and din can also be rewritten, and avalue LSB2OUT of the count portion 322 i for the second logic can alsobe rewritten.

When the potential of the negative-phase-sequence clock signal xck is atthe “L” level, and the potential of the positive-phase-sequence clocksignal ck is at the “H” level, the value LSB2IN of the count portion 321i+1 for the first digit belonging to the odd-numbered column i+1 isoutputted as each of the control signals RHB and XRLB. Also, an invertedvalue of the value LSB2IN is substituted (set) into the output node msa1of the flip-flop 52. As a result, the potential at the inner node msa0of the flip-flop 52 can also be rewritten. In addition, the potential atthe inner node msa0 is inverted in logic thereof in the order ofmsa1.fwdarw.din.fwdarw.sla0.fwdarw.sla1 to be transferred, whereby thepotentials at the nodes din, sla0 and sla1 can also be written, and thevalue LSB2OUT of the counter 322 i for the second digit can also bewritten.

Therefore, for the time period, for which both the potentials of the twocomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 are held at the “H” level, of the phase of the horizontaladdition mode, the value LSB2IN of the count portion 321 i+1 can bewritten to the value LSB2OUT of the counter 322 i for the second digit.When both the potentials of the two comparison results Vco(i) andVco(i+1) from the two comparators 31 i and 31 i+1 are at the “H” level,the value LSB2IN of the count portion 321 i+1 for the first digitbelonging to the odd-numbered column i+1 is set so that 1 is added tothe count portion for the second digit of the counter every one halfclock period. Therefore, when both the potentials of the two comparisonresults Vco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 areat the “H” level, the operation can be carried out so that 1 is added tothe count portion for the second digit of the counter every one halfclock period.

<LSB Circuit Belonging to Odd-Numbered Column>

FIG. 16 is a block diagram, partly in circuit, showing a concretecircuit configuration of the LSB count portion 321 i+1 belonging to thepixel column i+1 (the LSB circuit belonging to the odd-numbered column).The LSB circuit portion 321 i+1 in Embodiment 3 includes a latch portion61, a coherency control portion 62, and a stop control portion 63, anup/down control portion 64, and a selection portion 65.

The latch portion 61 receives as inputs thereof the control signal COB2outputted from the AND circuit 332 of the addition control portion 33,and the clock signal CK. The latch portion 61 holds therein a logicstate when the potential of the control signal COB2 transits from the“H” level to the “L” level.

Here, the control signal COB2 is a signal corresponding to the controlsignal COB1 used in the LSB count portion 321 i. The potential of thecontrol signal COB1 is usually held at the “L” level when no addition iscarried out. On the other hand, the control signal COB2 becomes thecomparison result Vco(i+1) from the comparator 31 i+1 when no additionis carried out.

The coherency control portion 62 controls whether a potential of anoutput starts with the “H” level or the “L” level for obtainingcoherency with the last count result, and holds information therefor inthe latch circuit 62. Specifically, the coherency control portion 62checks a logic state of a potential (an “H” level or an “L” level) at anode LATIN1 when the potential of the control signal FLIPLSB changesfrom the “L” level to the “H” level while the potential of the signalFLIPLSB changes in the order to the “L” level.fwdarw.the “H”level.fwdarw.the “L” level. Also, the coherency control portion 62controls whether the signal at the node LT should benon-inverting-transferred or inverting-transferred to the node FO whenthe potential of the control signal FLIPLSB changes from the “H” levelto the “L” level, and thus is set at the “L” level again.

The stop control portion 63 carries out the control so as to stop thecount portions in and after the count portion 322 i+1 for the seconddigit in the phase of the addition mode. Specifically, when a potentialof an addition mode signal ADD MODE is at the “H” level, and a potentialof an inverting addition mode signal XADD_MODE is set at the “L” level,the stop control portion 63 connects a node PD to a negative side powersource potential VSS, and fixes a potential at the node PD to the “L”level. As a result, the stop control portion 63 stops the count portionsin and after the count portion 322 i+1 for the second digit belonging tothe odd-numbered column i+1 in the phase of the addition mode. As aresult, it is possible to save the power consumption.

The up/down control portion 64 carries out the control relating towhether the up-count or the down-count should be carried out inaccordance with up/down change-over control signals UDSL and XUDSL.

The selection portion 65 selects whether the value LSB2IN of the countportion 321 i+1 for the first digit belonging to the odd-numbered columni+1 or the value LSB2OUT of the count portion 322 i for the second digitbelonging to the even-numbered column i should be transmitted to thenode LATIN1 of the coherency control portion 62.

Specifically, when the potential of the addition mode signal ADD MODE isat the “L” level, and the potential of the inverting addition modesignal XADD_MODE is at the “H” level, the selection portion 65 transmitsthe value LSB2IN of the count portion 321 i+1 for the first digitbelonging to the odd-numbered column i+1 to the node LATIN1. Therefore,the selection portion 65 operates as the normal counter LSB circuit inthe phase of the horizontal non-addition mode, thereby inputting thevalue LSB2IN of the count portion 321 i+1 for the first digit belongingto the odd-numbered column i+1 to the count portion 322 i+1 for thesecond digit from the LSB belonging to the odd-numbered column i+1.

In addition, when the potential of the addition mode signal ADD MODE isat the “H” level, and the potential of the inverting addition modesignal XADD_MODE is at the “L” level, the selection portion 65 transmitsthe value LSB2OUT of the count portion 322 i for the second digitbelonging to the even-numbered column i to the node LATIN1. Therefore,although the selection portion 65 operates as the LSB circuit in thephase of the horizontal addition mode as well, the selection portion 65inputs the value LSB2IN of the count portion 321 i+1 for the first digitbelonging to the odd-numbered column i+1 to the count portion 322 i forthe second digit from the count portion 321 i for the first digitbelonging to the even-numbered column i.

As a result, the value LSB2IN of the count portion 321 i+1 belonging tothe first digit is directly substituted as each of the control signalsRHA, XRLA, and RHB, XRLB (refer to FIG. 15) into the flip-flops 51 and52, respectively. In such a manner, when both the potentials of the twocomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 are at the “H” level, the operation can be carried out so that 1is added to the count portion 322 i for the second digit of the counter32 i belonging to the even-numbered column i every one half clock period(1-counting operation).

In the phase of the horizontal non-addition mode, when the value LSB2INof the count portion 321 i+1 for the first digit belonging to theodd-numbered column i+1 is at the “H” level in a state in which the darksignal has been done with the AD conversion, the control is carried outin such a way that the value LSB2IN starts with a change of the “H”level to the “L” level based on the operations of the coherency controlportion 62 and the selection portion 65. On the other hand, when thevalue LSB2IN of the count portion 321 i+1 for the first digit belongingto the odd-numbered column i+1 is at the “L” level in the state in whichthe dark signal has been done with the AD conversion, the control iscarried out in such a way that the value LSB2IN starts with a change ofthe “L” level to the “H” level.

In the phase of the horizontal addition mode, when the value LSB2OUT ofthe count portion 322 i for the second digit belonging to theeven-numbered column i is at the “H” level in a state in which the darksignal has been done with the AD conversion, the control is carried outin such a way that the value LSB2OUT starts with a change of the “H”level to the “L” level. On the other hand, when the value LSB2OUT of thecount portion 322 i for the second digit belonging to the even-numberedcolumn i is at the “L” level in the state in which the dark signal hasbeen done with the AD conversion, the control is carried out in such away that the value LSB2OUT starts with a change of the “L” level to the“H” level.

It is noted that in the phase of the horizontal addition mode, for atime period from end of the counting of the dark signal to start of thecounting of the luminance signal, the latch circuit 42 in the countportion 321 i for the first digit belonging to the even-numbered columni stores therein a least significant bit. In addition, for the timeperiod from end of the counting of the dark signal to start of thecounting of the luminance signal, the latch circuit 621 in the countportion 321 i+1 for the first digit belonging to the odd-numbered columni+1 stores therein the second bit from the least significant bit.

According to the column processing portion 13C in Embodiment 3 of thepresent invention described above, the addition for the pixels in thehorizontal direction is carried out within the column processing portion13C, thereby making it possible to reduce the amount of informationhorizontally outputted while the sensitivity is maintained similarly tothe case of each of the column processing portions 13A and 13B inEmbodiment 1 and 2. Therefore, it is possible to realize the enhancementof the frame rate, and the reduction of the power consumption. Inaddition thereto, the following operation and effect can be obtained.

In the column processing portion 13C in Embodiment 3, when one of thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 is at the “H” level, the two flip-flops 51and 52 are used in which the clock signals ck and xck each synchronizedwith the clock signal CK are received at the respective clock terminals.Also, the two flip-flops 51 and 52 are used in which when both thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 are at the “H” level, the control signals RHand XRL each synchronized with the clock signal CK are received at theset terminals and the reset terminals, respectively. As a result, whenboth the potentials of the comparison results Vco(i) and Vco(i+1) fromthe two comparators 31 i and 31 i+1 are at the “H” level, the countportion 322 i for the second digit of the counter 32 i can be caused tocarry out the 1-counting operation with one half clock period of theclock signal CK. On the other hand, when one of the potentials of thecomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 is at the “H” level, the count portion 322 i for the second digitof the counter 32 i can be caused to carry out the 1-counting operationwith one clock period of the clock signal CK.

In addition, the column processing portion 13C has the circuit (thelatch circuit 41 shown in FIG. 13) which passes the clock signal CK whenboth the potentials of the comparison results Vco(i) and Vco(i+1) fromthe two comparators 31 i and 31 i+1 are at the “H” level, and holdstherein the current signal level when at least one of the potentials ofthe comparison results Vco(i) and Vco(i+1) is at the “L” level.Moreover, the column processing portion 13C has the circuit (the latchcircuit 40 shown in FIG. 13) which passes the clock signal CK when atleast one of the potentials of the comparison results Vco(i) andVco(i+1) is at the “H” level, and holds therein the current signal levelwhen both the potentials of the comparison results Vco(i) and Vco(i+1)are at the “L” level. Also, when one of the potentials of the comparisonresults Vco(i) and Vco(i+1) is at the “H” level, the clock signal CK isoutputted through these two circuits. Thus, when the state in which whenone of the potentials of the comparison results Vco(i) and Vco(i+1) isat the “H” level starts, the output signal necessarily starts with therising to the “H” level. As s result, when both the potentials of thecomparison results Vco(i) and Vco(i+1) end at the “H” level, and thestate in which one of the potentials of the comparison results Vco(i)and Vco(i+1) is at the “L” level starts, a rising portion of the clocksignal CK can be firstly outputted.

Moreover, the column processing portion 13C does not specially have acircuit which operates as the LSB circuit when both the potentials ofthe comparison results Vco(i) and Vco(i+1) from the two comparators 31 iand 31 i+1 are at the “H” level, and which carries out the 1-countingoperation every one half clock period in the count portion 322 i for thesecond digit of the counter 32 i. Likewise, the column processingportion 13C does not specially have a circuit which operates as the LSBcircuit when one of the potentials of the comparison results Vco(i) andVco(i+1) from the two comparators 31 i and 31 i+1 is at the “H” level,and which carries out the 1-counting operation every one clock period inthe count portion 322 i for the second digit of the counter 32 i.

That is to say, the column processing portion 13C does not speciallyhave the portions of the two circuits described above, but adopts thecircuit configuration of using the portion of the circuit which operatesas the LSB circuit in the phase of the non-addition mode belonging tothe even-numbered column i, and the portion of the circuit whichoperates as the LSB circuit in the phase of the non-addition modebelonging to the odd-numbered column i+1. As a result, the occupationarea of the circuits can be made very small because it is possible toobtain the configuration in which the function of the addition for thepixels in the horizontal direction is given with the very less increasein number of transistors (for example, the number of transistorsincreases by 78 every two pixel columns as compared with the case of noaddition).

Here, the portion of the circuit which operates as the LSB circuit inthe phase of the non-addition mode belonging to the even-numbered columni is the count portion 321 i for the first digit belonging to theeven-numbered column. The count portion 321 i has the function of thecircuit which operates as the LSB circuit when one of the potentials ofthe comparison results Vco(i) and Vco(i+1) from the two comparators 31 iand 31 i+1 is at the “H” level in the phase of the addition mode. Inaddition, the portion of the circuit which operates as the LSB circuitin the phase of the non-addition mode belonging to the odd-numberedcolumn i+1 is the circuit portion 321 i+1 for the first digit belongingto the odd-numbered column. The count portion 321 i+1 has the functionof the circuit which operates as the LSB circuit when both thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 are at the “H” level in the phase of theaddition mode.

It should be noted that in Embodiment 3 as well, similarly to the caseof Embodiment 1, in the phase of the horizontal addition mode, theaddition control portion 33 carries out the control under which thecounting operation of the counter, not using the addition for thepixels, of the paired two counters 32 i and 32 i+1 is stopped, therebymaking it possible to save the power consumption.

Embodiment 4

FIG. 17 is a block diagram, partly in circuit, showing a configurationof a column processing portion 13D in an image pickup device accordingto Embodiment 4 of the present invention. In the figure, the sameportions as those in FIG. 3 are designated with the same referencenumerals or symbols, respectively. In this case as well, a circuitconfiguration of two pixel columns, i.e., an i-th column, and an(i+1)-th column is shown.

The column processing portion 13D in Embodiment 4 is identical inconfiguration to the column processing portion 13A in Embodiment 1 inthat the column processing portion 13D includes comparators 31 i and 31i+1, and the counters 32 i and 32 i+1 which are each provided so as tocorrespond to the two pixel columns i and i+1, respectively.

The column processing portion 13A in Embodiment 1 uses the SDR counterwhich carries out the counting operation for counting 1 with one periodof the clock signal CK with respect to all the digits of each of thecounters 32 i and 32 i+1. On the other hand, the column processingportion 13D in Embodiment 4 adopts the following configuration withrespect to one of the two counters 32 i and 32 i+1, for example, thecounter 32 i.

That is to say, in one counter 32 i, a configuration that a DDR counter3211 as a first count portion, and an SDR counter 3212 as a second countportion are used in combination in the count portion 321 i for the firstdigit.

The DDR counter 3211 carries out the counting operation for counting 1with one half clock period. The SDR counter 3212 carries out thecounting operation for counting 1 with one clock period. Also, the SDRcounter is used as each of count portions in and after the count portion322 i for the second digit similarly to the case of Embodiment 1.

In the other counter 32 i+1, the DDR counter is used as the countportion 321 i+1 for the first digit. Also, the SDR counter is used aseach of count portions in and after the count portion 322 i+1 for thesecond digit similarly to the case of Embodiment 1.

Also, the feature of the addition control portion 33 is that in thephase of the addition mode, the count portion 321 i for the first digitof the counter 32 i is controlled as follows based on the potentials ofthe comparison results Vco(i) and Vco(i+1) from the two comparators 31 iand 31 i+1. FIG. 18 shows a relationship of timings for the control.

When both the potentials of the comparison results Vco(i) and Vco(i+1)from the two comparators 31 i and 31 i+1 are at the “H” level, theaddition control portion 33 instructs the count portion 321 i for thefirst digit to carry out the 1-counting operation for counting 1 withone half clock period. In addition, when one of the potentials of thecomparison results Vco(i) and Vco(i+1) from the two comparators 31 i and31 i+1 are at the “H” level, the addition control portion 33 instructsthe count portion 321 i for the first digit to carry out the 1-countingoperation for counting 1 with one clock period. Moreover, both thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 are at the “L” level, the addition controlportion 33 instructs the count portion 321 i for the first digit to stopthe 1-counting operation.

More specifically, when both the potentials of the comparison resultsVco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 are at the“H” level, the addition control portion 33 instructs the DDR counter3211 to carry out the 1-counting operation, thereby carrying out theaddition for the pixels at double speed (multiple) count. The additionalcontrol portion 33 switches the counter for the carrying out thecounting operation from the DDR counter 3211 over to the SDR counter3212 at a time point when one of the potentials of the comparisonresults Vco(i) and Vco(i+1) from the two comparators 31 i and 31 i+1 isinverted from the “H” level to the “L” level, thereby carrying out thenormal counting operation.

Here, only the count portion 321 i for the first digit is made to havethe synchronization at the falling, thereby making it possible toprevent the counter for carrying out the counting operation from beingswitched from the DDR counter 3211 over to the SDR counter 3212 withinthe same clock. Also, the counting operation of the count portion 321 ifor the first digit is stopped at a time point when both the potentialsof the comparison results Vco(i) and Vco(i+1) from the two comparators31 i and 31 i+1 are inverted.

As has been described, when in the horizontal addition mode, both thepotentials of the comparison results Vco(i) and Vco(i+1) from the twocomparators 31 i and 31 i+1 are at the “H” level, the count portion 321i for the first digit of the counter 32 i is caused to carry out thecounting operation at the double speed, thereby making it possible toobtain the following effect. That is to say, since the addition for thepixels in the horizontal direction can be realized without increasing atime period for the AD conversion within the column processing portion13D, the amount of information horizontally outputted can be reduced toone half while the sensitivity is maintained. As a result, it ispossible to realize the enhancement of the frame rate, and the reductionof the power consumption.

It is noted that in Embodiment 4, the first logic is set as the “H”level, and the second logic is set as the “L” level. Also, when thepixel signals Vsig(i) and Vsig(i+1) are each lower in level than thereference signal REF, the comparators 31 i and 31 i+1 output thecomparison results Vco(i) and Vco(i+1) each at the “H” level, and whenthe pixel signals Vsig(i) and Vsig(i+1) are each higher in level thanthe reference signal REF, the comparators 31 i and 31 i+1 output thecomparison results Vco(i) and Vco(i+1) each at the “L” level. However,this logic may be inverted. That is to say, a configuration may also beadopted such that when the pixel signals Vsig(i) and Vsig(i+1) are eachlower in level than the reference signal REF, the comparators 31 i and31 i+1 output the comparison results Vco(i) and Vco(i+1) each at the “L”level (first logic), and when the pixel signals Vsig(i) and Vsig(i+1)are each higher in level than the reference signal REF, the comparators31 i and 31 i+1 output the comparison results Vco(i) and Vco(i+1) eachat the “H” level (second logic).

(Addition for Pixels in Both Horizontal and Vertical Directions)

Although in each of Embodiments 1 to 4 described above, basically, theaddition for the pixels in the horizontal direction has been describedso far, the addition for the pixels in the horizontal direction and theaddition for the pixels in the vertical direction are used incombination, thereby making it possible to realize the furtherenhancement of the frame rate. FIG. 19 shows a relationship between thecomparators 31 i and 31 i+1, and the pixels when the addition for the(2.times.2) pixels in both the horizontal and vertical directions iscarried out. As shown in the figure, in the case of being colorcompatible, one comparator 31 is provided so as to correspond to twopixel columns as a unit. Thus, two sets of pixel columns are suitablyswitched over to each other by change-over switches SWi and SWi+1provided between the two sets of pixel columns, and the comparators 31 iand 31 i+1, respectively.

Hereinafter, a processing procedure when the addition for the pixels inboth the horizontal and vertical directions is carried out will bedescribed with reference to a flow chart of FIG. 20.

Firstly, the counters 32 i and 32 i+1 are initialized (step S11). Next,pixels B22 and B42 are connected to the comparators 31 i and 31 i+1 bythe change-over switches SWi and SWi+1, respectively, and dark signalinformation from the pixels B22 and B42 is read out to the verticalsignal line 17 (Step S12). Next, a sum of the dark signal informationfrom the pixels B22 and B42 is AD-converted, and subtraction is carriedout for the counter 32 i (Step S13). Next, the pixels B22 and B42 areconnected to the comparators 31 i and 31 i+1 by the switches SWi andSWi+1, respectively, and luminance information from the pixels B22 andB42 is read out to the vertical signal line 17 (Step S14). Next, a sumof the luminance information from the pixels B22 and B42 isAD-converted, and addition is carried out for the counter 32 i (StepS15).

Next, the pixels B24 and B44 are connected to the comparators 31 i and31 i+1 by the switches SWi and SWi+1, respectively, and dark signalinformation from the pixels B24 and B44 is read out to the signal line17 (Step S16). Next, a sum of the dark signal information from thepixels B24 and B44 is AD-converted, and subtraction is carried out forthe counter 32 i (Step S17). Next, the pixels B24 and B44 are connectedto the comparators 31 i and 31 i+1 by the switches SWi and SWi+1,respectively, and luminance information from the pixels B24 and B44 isread out to the vertical signal line 17 (Step S18). Next, a sum ofluminance information from the pixels B24 and B44 is AD-converted, andaddition is carried out for the counter 32 i (Step S19).

After that, the resulting information is transferred to the outside ofthe column processing portion 13 (Step S20). When the column processingportion 13D includes a latch for holding therein a storage state whilethe horizontal transfer is waited for, parallel processing for theprocessing process becomes possible. That is to say, the process fromthe process for initializing the counters 32 i and 32 i+1 to the processfor AD-converting the sum of the luminance information from the pixelsB24 and B44, and carrying out the addition for the counter 32 i (StepsS11 to S19), and the process for transferring the resulting informationto the outside (Step S20) can be processed in parallel with each other.The frame rate can be made higher in the case where the parallelprocessing is executed in such a manner than in the case where noparallel processing is executed.

From the foregoing, the addition for the pixels in both the horizontaland vertical directions can be realized for the vertical signal line 17by a combination with the related technique of the addition for thepixels in the vertical direction (for example, the technique disclosedin Patent Document 1). This technique can be readily expanded toaddition for (3.times.3) pixels in both horizontal and verticaldirections, or the like. In addition, this technique can be combinedwith a technique of addition for pixels in a vertical direction based onaccumulation of the electric charges from a plurality of pixels infloating diffusion within a pixel. In this case as well, it is possibleto realize the addition for the pixels in both the horizontal andvertical directions.

In the above, although the description has been focused on the casewhere the addition for the pixels made under the control by the additioncontrol portion 33 is carried out, of course, the CMOS image sensoraccording to an embodiment of the present invention can also be appliedto the case where no addition for the pixels is carried out. Also, whenno addition for the pixels is carried out, with regard to the controlsignals COB0, COB1 and COB2 outputted from the addition control portion33, a relationship of COB0=Vco(i), COB1=“L” level, and COB2=Vco(i+1) isestablished. That is to say, the relationship of COB0=Vco(i), COB1=“L”level, and COB2=Vco(i+1) is established, whereby the processing when noaddition for the pixels is carried out is executed.

It should be noted that although the control signals COB0, COB1 and COB2need to be switched between the case where the addition for the pixelsis carried out and the case where no addition for the pixels is carriedout, a circuit for switching the control signals COB0, COB1 and COB2 isomitted here for the sake of simplicity of the description.

[Change]

Each of Embodiments 1 to 4 has been described by giving the case wherethe present invention is applied to the CMOS image sensor in which theunit pixels each adopted to detect the signal charges corresponding tothe light quantity of the visible light as the physical quantity aredisposed in the matrix as the example. However, the present invention isby no means limited to the application to the CMOS image sensor, andthus can be applied to the general solid-state image pickup device,utilizing the column system, in which the column processing portion isdisposed every pixel column of the pixel array portions.

Moreover, the present invention can be applied not only to thesolid-state image pickup device in which the pixels of the pixel arrayportion are successively scanned and selected in columns, and thesignals are read out from the pixels belonging to the selected column,respectively, but also to the X-Y address type solid-state image pickupdevice in which arbitrary pixels are selected in pixels, and signals areread out from the selected pixels in pixels, respectively.

It should be noted that the solid-state image pickup device may beformed in the form of one-chip or may have a module-like form, having animage capturing function, in which an image pickup portion, and a signalprocessing portion or an optical system are collectively packaged.

In addition, the present invention is by no means limited to theapplication to the solid-state image pickup device, and thus can beapplied to an image pickup apparatus as well. Here, the image pickupapparatus means the camera system such as the digital still camera orthe video camera, or the electronic apparatus, having the imagecapturing function, such as the mobile phone. It should be noted thatthe module-like form mounted to the electronic apparatus, that is, thecamera module is said as the image pickup apparatus in some cases.

[Image Pickup Apparatus]

FIG. 21 is a block diagram showing a configuration of an image pickupapparatus according to an embodiment of the present invention. As shownin FIG. 21, the image pickup apparatus 100 according to an embodiment ofthe present invention includes an optical system having a lens group 101and the like, an image pickup device 102, a DSP circuit 103 as a camerasignal processing circuit, a frame memory 104, a display device 105, arecording device 106, a manipulation system 107, a power source system108, and the like. Also, the DSP circuit 103, the frame memory 104, thedisplay device 105, the recording device 106, the manipulation system107, and the power source system 108 are connected to one anotherthrough a bus line 109.

The lens group 101 captures an incident light (image light) from anobject to image the incident light on an imaging area of the imagepickup element 102. The image pickup element 102 converts the lightquantity of the incident light imaged on the imaging area by the lensgroup 101 into electrical signals in pixels, and outputs the resultingelectrical signals as pixel signals. The CMOS image sensor having thecolumn processing portion in any of Embodiments 1 to 4 described aboveis used as the image pickup element 102.

The display device 105 is composed of a panel type display device suchas a liquid crystal display device or an organic electro luminescence(EL) display device, and displays thereon a moving image or a stillimage captured by the image pickup element 102. The recording device 106records image data on the moving image or the still image captured bythe image pickup element 102 in a recording medium such as a video tapeor a Digital Versatile Disk (DVD).

The manipulation system 107 issues manipulation commands about variouskinds of functions, which the image pickup apparatus 100 has, under themanipulations made by a user. The power source system 108 suitablysupplies various kinds of power sources as operation power sources forthe DSP circuit 103, the frame memory 104, the display device 105, therecording device 106, and the manipulation system 107 to those objectsfor supply.

The present application contains subject matter related to thatdisclosed in Japanese Priority Patent Application JP 2008-161415 filedin the Japan Patent Office on Jun. 20, 2008, and Japanese PriorityPatent Application JP 2008-260302 filed in the Japan Patent Office onOct. 7, 2008, the entire contents of which are hereby incorporated byreference.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

1. A solid-state imaging device, comprising: a plurality of pixelsincluding a first pixel configured to output a first analog signal, anda second pixel configured to output a second analog signal; a pluralityof comparators including a first comparator configured to compare thefirst analog signal with a reference signal and output a firstcomparison result, and a second comparator configured to compare thesecond analog signal with the reference signal and output a secondcomparison result; a first counter configured to receive the firstcomparison result and the second comparison result when a control signalis indicative of an active state, and receive the first comparisonresult when the control signal is indicative of a non-active state; anda second counter configured to receive the second comparison result whenthe control signal is indicative of the non-active state.
 2. Thesolid-state imaging device according to claim 1, wherein the pluralityof pixels are arranged in a matrix; the first pixel is disposed in afirst column of the matrix; and the second pixel is disposed in a secondcolumn of the matrix.
 3. The solid-state imaging device according toclaim 2, wherein the first column and the second column are adjacent toone another.
 4. The solid-state imaging device according to claim 1,further comprising an addition control circuit configured to perform anaddition operation on the first comparison result and the secondcomparison result.
 5. The solid-state imaging device according to claim4, further comprising: a third counter that is electrically connected tothe addition control circuit, wherein the plurality of pixels includes athird pixel configured to output a third analog signal, the plurality ofcomparators includes a third comparator configured to compare the thirdanalog signal with the reference signal and output a third comparisonresult, and the addition control circuit is further configured toreceive the third comparison result, output the third comparison resultto the first counter in response to determining that the control signalis indicative of the active state, and output the third comparisonresult to the third counter in response to determining that the controlsignal is indicative of the non-active state.
 6. The solid-state imagingdevice according to claim 5, wherein: the plurality of pixels arearranged in a matrix; the first pixel is disposed in a first column ofthe matrix; the second pixel is disposed in a second column of thematrix; and the third pixel is disposed in a third column of the matrix,wherein the first column and the second column are adjacent to oneanother, and the second column and the third column are adjacent to oneanother.
 7. The solid-state imaging device according to claim 6, whereinthe addition control circuit is further configured to perform a secondaddition operation on two of the first comparison result, the secondcomparison result, and the third comparison result.
 8. The solid-stateimaging device according to claim 6, wherein the addition controlcircuit is further configured to perform a third addition operation onall of the first comparison result, the second comparison result, andthe third comparison result.
 9. The solid-state imaging device accordingto claim 1, wherein respective ones of the plurality of pixels include aphotoelectric conversion element and a plurality of transistors.
 10. Thesolid-state imaging device according to claim 1, wherein the referencesignal has a ramp-like waveform.
 11. An electronic apparatus,comprising: an optical system; and a solid-state imaging deviceincluding: a plurality of pixels including a first pixel configured tooutput a first analog signal, and a second pixel configured to output asecond analog signal, a plurality of comparators including a firstcomparator configured to compare the first analog signal with areference signal and output a first comparison result, and a secondcomparator configured to compare the second analog signal with thereference signal and output a second comparison result, a first counterconfigured to receive the first comparison result and the secondcomparison result when a control signal is indicative of an activestate, and receive the first comparison result when the control signalis indicative of a non-active state; and a second counter configured toreceive the second comparison result when the control signal isindicative of the non-active state.
 12. The electronic apparatusaccording to claim 11, wherein: the plurality of pixels are arranged ina matrix; the first pixel is disposed in a first column of the matrix;and the second pixel is disposed in a second column of the matrix. 13.The electronic apparatus according to claim 12, wherein the first columnand the second column are adjacent to one another.
 14. The electronicapparatus according to claim 11, wherein the solid-state imaging devicefurther includes an addition control circuit configured to perform anaddition operation on the first comparison result and the secondcomparison result.
 15. The electronic apparatus according to claim 14,further comprising a third counter that is electrically connected to theaddition control circuit, wherein the plurality of pixels includes athird pixel configured to output a third analog signal, the plurality ofcomparators includes a third comparator configured to compare the thirdanalog signal with the reference signal and output a third comparisonresult, and the addition control circuit is further configured toreceive the third comparison result, output the third comparison resultto the first counter in response to determining that the control signalis indicative of the active state, and output the third comparisonresult to the third counter in response to determining that the controlsignal is indicative of the non-active state.
 16. The electronicapparatus according to claim 15, wherein: the plurality of pixels arearranged in a matrix; the first pixel is disposed in a first column ofthe matrix; the second pixel is disposed in a second column of thematrix; and the third pixel is disposed in a third column of the matrix,wherein the first column and the second column are adjacent to oneanother, and the second column and the third column are adjacent to oneanother.
 17. The electronic apparatus according to claim 16, wherein theaddition control circuit is configured to perform a second additionoperation on two of the first comparison result, the second comparisonresult, and the third comparison result.
 18. The electronic apparatusaccording to claim 16, wherein the addition control circuit isconfigured to perform a third addition operation on all of the firstcomparison result, the second comparison result, and the thirdcomparison result.
 19. The electronic apparatus according to claim 11,wherein respective ones of the plurality of pixels include aphotoelectric conversion element and a plurality of transistors.
 20. Theelectronic apparatus according to claim 11, wherein the reference signalhas a ramp-like waveform.